Red Cabbage Microgreens Lower Circulating Low-Density

Nov 12, 2016 - Cardiovascular disease (CVD) is the leading cause of death in the United States, and hypercholesterolemia is a major risk factor. Popul...
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Red cabbage microgreen lower circulating LDL, liver cholesterol and inflammatory cytokines in mice fed a high fat diet Haiqiu Huang, Xiaojing Jiang, Zhenlei Xiao, Lu Yu, Quynhchi Pham, Jianghao Sun, Pei Chen, Wallace Yokoyama, Liangli (Lucy) Yu, Yaguang Luo, and Thomas T. Y. Wang J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b03805 • Publication Date (Web): 12 Nov 2016 Downloaded from http://pubs.acs.org on November 17, 2016

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Journal of Agricultural and Food Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

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Journal of Agricultural and Food Chemistry

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Red cabbage microgreen lower circulating LDL, liver cholesterol and inflammatory

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cytokines in mice fed a high fat diet

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Haiqiu Huang ‡,† , Xiaojing Jiang †, Zhenlei Xiao §,∥, Lu Yu †, Quynhchi Pham ‡, Jianghao

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Sun ¶, Pei Chen ¶, Wallace Yokoyama ⊥, Liangli (Lucy) Yu †, Yaguang (Sunny) Luo §,

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Thomas T.Y. Wang ‡,*

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9

Research Center, Beltsville, MD 20705

USDA, ARS, Diet, Genomics and Immunology Lab, Beltsville Human Nutrition

10



11

20742

12

§

USDA, ARS, Food Quality Lab, Beltsville Area Research Center, Beltsville, MD 20705

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Department of Agriculture, Culinology and Hospitality Management, Southwest

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Minnesota State University, Marshall, MN 56258

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16

Research Center, Beltsville, MD 20705

17

⊥ USDA,

18

Center, Albany, CA 94710

Nutrition and Food Science Department, University of Maryland, College Park, MD

Food Composition and Methods Development Laboratory, Beltsville Human Nutrition

ARS, Healthy Processed Foods Research Unit, Western Regional Research

19 20

* Contact Information of the Corresponding Author: Thomas T. Y. Wang, Ph.D.

21

Tel: 301-504-8459; Email: [email protected]

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Mailing Address: 10300 Baltimore Ave., USDA-ARS, BHNRC, Bldg. 307C, Rm 132,

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Beltsville, MD 20705

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Journal of Agricultural and Food Chemistry

ABSTRACT

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Cardiovascular disease (CVD) is the leading cause of death in the United States

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and hypercholesterolemia is a major risk factor. Population studies, as well as animal and

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intervention studies, support the consumption of a variety of vegetables as a means to

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reduce CVD risk through modulation of hypercholesterolemia. Microgreens of a variety

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of vegetables and herbs have been reported to be more nutrient dense compared to their

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mature counterparts. However, little is known about the effectiveness of microgreens to

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affect lipid and cholesterol levels. The present study used a rodent diet-induced obesity

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(DIO) model to address this question. C57BL/6NCr mice (n=60, male, five-week old)

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were randomly assigned to six feeding groups: 1) low fat diet; 2) high fat diet; 3) low fat

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diet+1.09% red cabbage microgreens; 4) low fat diet+1.66% mature red cabbage; 5) high

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fat diet+1.09% red cabbage microgreens; 6) high fat diet+1.66% mature red cabbage. The

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animals were on their respective diets for eight weeks. We found microgreen

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supplementation attenuated high fat diet induced weight gain. Moreover, supplementation

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with microgreens significantly lowered circulating LDL levels in animals fed the high fat

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diet, reduced hepatic cholesterol ester and triacylglycerol levels and expression of

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inflammatory cytokines in the liver. These data suggest that microgreens can modulate

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weight gain and cholesterol metabolism, and may protect against CVD by preventing

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hypercholesterolemia.

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Keywords: cholesterol, inflammation, microgreen, red cabbage, triacylglycerol

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INTRODUCTION

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Chronic diseases account for about 70% of deaths and more than 75% of total healthcare

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costs in the U.S. in 2010 1. In 2012, close to half of U.S. population were reported to have

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one or more chronic conditions 2, and cardiovascular disease (CVD) in particular,

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accounted for 30% of all U.S deaths 3. Epidemiological studies indicate that individuals

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with higher intakes of fruits and vegetables tend to have a lower occurrence of CVD 4.

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Therefore, increased consumption of fruits and vegetables has been recommended as a

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key component of a healthy diet for the prevention of chronic diseases, including CVD 4,

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5

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cruciferous vegetables, may be particularly beneficial for human health

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vegetables, such as red cabbage, have been reported to be protective against chronic

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diseases such as CVD and prostate cancer 7, 8.

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As part of the concerted strategy to promote health and prevent chronic diseases,

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development of new foods with enhanced function, i.e. functional foods, has received

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much attention. Microgreens, an exotic genre of edible greens (Figure 1), is one of those

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foods that has gained popularity in upscale markets and restaurants over the past few

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years 9, 10. Microgreens are tender immature plants produced from the seeds of vegetables

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(such as red cabbage) and herbs, having two fully developed cotyledon leaves with or

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without the emergence of a rudimentary pair of first true leaves. Microgreens can provide

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a large array of intense flavors, vivid colors and tender textures 10 and can be served as an

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ingredient in salads, soups, and sandwiches, to enhance their color, texture, and/or flavor.

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Microgreens also serve as an edible garnish to brighten up a wide variety of main dishes.

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More importantly, previous studies found that microgreens possess higher nutritional

. Moreover, there is growing evidence that certain groups of vegetables, such as

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5, 6

. Cruciferous

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densities when compared to the mature counterparts

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microgreens contained approximately 260-fold more β-carotene, over 40 times more

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vitamin E and 2.4-6-fold higher vitamin C levels than previously published for mature

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red cabbage 11.

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Although microgreens, such as those from red cabbage have been reported to possess

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more nutrients and perceived to be “healthier”, no known study has been conducted to

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evaluate whether consumption reduces CVD risk factors. Previous research has reported

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potential health promoting properties of red cabbage, such as antioxidant, anti-

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inflammation, and antibacterial effects, and amelioration of dyslipidemia induced by

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excessive cholesterol

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cruciferous vegetables, we hypothesized that red cabbage microgreen (RCMG) would

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reduce CVD risk factors in a DIO mouse model. The current study tested this hypothesis

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and our results supported that consumption of RCMG, at physiologically achievable

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levels,

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hypercholesterolemia and liver inflammation. Elevated levels of circulating lipid and

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cholesterol are known risk factors for CVD, therefore, DIO mouse model was employed

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to access the effect of RCMG to ameliorate dyslipidemia and hypercholesterolemia

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induced by high fat diet 15-17. Additionally, possible molecular mechanisms for the health

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promoting effects of RCMG were evaluated.

attenuates

12-14

. For example, red cabbage

. Based on the existing literature on the protective effects of

several

high

fat

diet-induced

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risk

factors,

including

Journal of Agricultural and Food Chemistry

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MATERIALS AND METHODS

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Sample preparation. Mature red cabbage samples (Brassica oleracea L. var.

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capitata) were obtained from a local market. Red cabbage microgreens (B oleracea L. var.

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capitata) were provided by a commercial microgreens grower (Fresh Origins, San Marcos,

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CA, USA). Microgreens, 7 days after seeding, were harvested without roots, packaged in

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clamshell containers and shipped overnight in insulated containers with ice packs. When

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received, all the mature and microgreen samples were flash frozen in liquid nitrogen and

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lyophilized for 48-72 h (VirTis Freezemobile 35 ES Sentry 2.0 freeze-dryer, SP Scientific

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Corp., Warminster, PA, USA). Lyophilized samples were then ground into powder and

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stored in sealed bags at -20 °C before use.

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Bioactive composition analysis. Major bioactive components (anthocyanin,

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polyphenols, and glucosinolates) in the stock mature red cabbage and red cabbage

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microgreen to be used for the formulation of animal diets were analyzed. The extraction

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and analysis protocols are as follows.

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Anthocyanin and polyphenol extraction from microgreen and mature red cabbage.

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Freeze-dried and powdered microgreen and mature red cabbage samples (200 mg) were

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extracted with 5.00 mL of methanol-water (70:30, v/v) using sonication for 60 min at

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room temperature. The extracts were then centrifuged at 5,000 g for 15 minutes (IEC

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Clinical Centrifuge, Damon/IEC Division, Needham, MA, USA) and the supernatant was

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filtered through a 17 mm (0.45 µm) PVDF syringe filter (VWR Scientific, Seattle, WA,

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USA). Five µL of the filtered extract was used for UHPLC-PDA-ESI/HRMS/MSn

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analysis described below.

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Journal of Agricultural and Food Chemistry

Extraction of glucosinolates. Glucosinolates in microgreen and mature red 18

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cabbage were isolated according to previously published methods.

Briefly, 100 mg

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freeze-dried and powdered microgreen and mature red cabbage samples were heated at

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75 ⁰C for 1 min, mixed with 5 mL methanol solution and then vortexed for 20 s. Sinigrin

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solution (5 mM, 200 µL) was added as internal standard in one set of samples and 200 µL

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methanol in the other set as control. Extraction solutions were heated with boiling

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methanol for 20 minutes, filtered with 0.45 µm syringe filter, and supernatants were

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transferred to another tube for future use. Then 1 mL extract was added to a pre-treated

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DEAE Sephadex A25 resin mini-column and then add 100 µL of sulfatase solution,

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leave to act overnight at ambient temperature and then eluted with two 1mL portions of

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water. Five µL of the purified extract was used for UHPLC-PDA-ESI/HRMS/MSn

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analysis described below.

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UHPLC-PDA-ESI/HRMS/MSn Conditions. UHPLC-PDA-ESI/HRMS/MSn was

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used to determine anthocyanin, polyphenol, and glucosinolates amount and species. The

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UHPLC-HRMS system used consisted of an LTQ Orbitrap XL mass spectrometer with

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an Agilent 1290 UHPLC with G4220A binary pump, 1316C column oven, and G4226

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auto sampler with temperature control and a PDA detector (ThermoFisher Scientific, San

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Jose, CA). Anthocyanin and polyphenol separation were carried out on a Hypersil Gold

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AQ RP- C18 UHPLC column (200 mm × 2.1 mm i.d., 1.9 µm, ThermoFisher Scientific)

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with an UltraShield pre-column filter (Analytical Scientific Instruments, Richmond, CA)

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at a flow rate of 0.3 mL/min. A gradient mobile phase was used in this study (96% A (1%

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formic acid in water) and 4% B (1% formic acid in ACN) at 0 min, 80% A and 20% B at

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20 min, 65% A and 35% B at 40 min, 25% A and 75% B at 45 min, and 10% A, and 90% 7 ACS Paragon Plus Environment

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B at 50 - 55 min) with an injection volume of 5 µL, column temperature at 50 ºc and

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sample temperature at 4 ºC.

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Glucosinolates separation was carried out on an RRHD Eclipseplus C18 column

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(150 mm × 2.1 mm i.d., 1.8 µm, Agilent) with an UltraShield pre-column filter

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(Analytical Scientific Instruments, Richmond, CA) at a flow rate of 0.4 mL/min. A

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gradient mobile phase was used in this study (98% A (1% formic acid in water) and 2%

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B (1:1 v:v of 1% formic acid in ACN) at 0 min, 90% A and 10% B at 10 min, 50% A and

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50% B at 25 min, and 10% A, and 90% B at 30 min) with an injection volume of 5 µL,

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column temperature at 50 ºC and sample temperature at 4 ºC, and UV detection

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wavelength at 229 nm. For determination of anthocyanin, cyanidin 3-O-glucoside

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reference standard was used for determination of total anthocyanins by assuming molar-

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response factor as 1.00 (UV 520nm). Rutin (quercetin-3-O-rutinoside) reference standard

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was used for determination of other polyphenols by assuming molar-response factor as

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1.00 (UV 330 nm). 19 Identification of anthocyanin and other polyphenols were made by

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comparing with the published literature by using high-resolution MS data, MS2-4

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fragmentation and UV-vis data. 20 An LTQ Orbitrap XL mass spectrometer was used for

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the confirmation of each individual glucosinolates. The optimized conditions were set as

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follows: sheath gas at 70 (arbitrary units), aux and sweep gas at 15 (arbitrary units), spray

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voltage at 4.8 kV, capillary temp at 270 °C, capillary voltage at 15 V, and tube lens at 70

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V. The mass range was from 100 to 1000 amu with a resolution of 30,000, FTMS AGC

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target at 2e5, FT-MS/MS AGC target at 1e5, isolation width of 1.5 amu, and max ion

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injection time of 500 ms. Source CID was set at 20%. The most intense ion was selected

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for the data-dependent scan to offer their MS2 to MS3 product ions, respectively, with

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normalization collision energy at 35%. The type and amount of desulfo-glucosinolates

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(desulfo-GLs) were calculated using known concentrations of standard sinigrin and

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recommended relative response factors with PDA signal at 229 nm (Table 3)

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(Supplemental Fig. 4). GLs were identified based on their specific accurate masses (as

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desulfo form) and retention times.

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Animals and diets. Male C57BL/6NCr mice, aged 5 weeks (approximately 20 g),

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were purchased from Charles River Laboratories (National Cancer Institute, Frederick,

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MD, USA). Mice were single-housed in a temperature-controlled room with a 12 h/12 h

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day-night cycle. Prior to the experiment, they were fed a standard rodent chow and had

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free access to water for 1 week to acclimatize to the environment. For the experiment, a

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total of 60 mice were randomly divided into six groups (10 mice/group) and fed one of

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six different diets: 1) low-fat diet (LF) (10 kcal% fat diet); 2) low-fat diet supplemented

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with red cabbage microgreen powder (LFMG) (10 kcal% fat diet containing 10.9 g/kg

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diet); 3) low-fat diet supplemented with mature red cabbage powder (LFRC) (10 kcal%

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fat diet containing 16.6 g/kg diet); 4) a high-fat diet (HF) (45 kcal% fat diet); 5) a high-fat

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diet supplemented with red cabbage microgreen powder (HFMG) (45 kcal% fat diet

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containing 10.9 g/kg diet); 6) high-fat diet supplemented with mature red cabbage

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powder (HFRC) (45 kcal% fat diet containing 16.6 g/kg diet). The experimental diets

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were formulated and pelleted by Research Diets (New Brunswick, NJ, USA). Animals

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(10 per group) were fed the respective diets for 8 weeks with water available ad libitum.

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Food intake and body weight were recorded once a week. All the low fat diets consisted

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of 20% protein, 70% carbohydrate, and 10% fat on a caloric basis and the high fat diets

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consisted of 20% protein, 35% carbohydrate, and 45% fat on a caloric basis. Red cabbage

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microgreens and mature red cabbage samples were added into diets in the form of dry

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powder and the amount supplemented into diets for the mice calculated based on the

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equivalence of 200 g vegetables/day/person (60 kg) using the Dose Translation Formula

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(Reagan-Shaw, et al., 2007). Detailed information of diet compositions is shown in Table

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1. All animal experiments were conducted under an animal study protocol (Protocol #:

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14-006) that was reviewed and approved by the USDA, ARS, Beltsville Area

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Institutional Animal Care and Use Committee (IACUC).

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Plasma, tissue and fecal sample collection. Mice were subjected to a 12 h fast

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with water available ad libitum. Mice were anesthetized in a CO2 chamber and blood was

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collected by cardiac puncture with syringes previously rinsed with potassium EDTA

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solution (15% w/v), and plasma was separated by centrifugation at 1,300 rcf for 10 min at

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4 °C. Livers were collected and an aliquot of the tissue was immediately frozen in liquid

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nitrogen for later analysis, the other preserved in RNA Stabilization Solution (Ambion,

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Austin, TX, USA) and kept at -80 °C. At the end of the eighth week, 24 h fecal samples

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were also collected from the bottom of the cage and stored at -80 °C.

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Plasma lipoprotein analysis. Plasma lipoprotein cholesterol concentrations were

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determined by size exclusion chromatography as previously described (German, et

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al.,1996). Briefly, an Agilent 1100 chromatograph was employed with a postcolumn

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derivatization reactor, consisting of a mixing coil (1615-50 Bodman, Aston, PA, USA) in

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a temperature-controlled water jacket (Aura Industrials, Staten, NY, USA). A Hewlett-

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Packard (Agilent, Palo Alto, CA, USA) HPLC pump 79851-A was used to deliver the

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cholesterol reagent (Roche Diagnostics, Indianapolis, IN, USA) at a flow rate of 0.2

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mL/min. Bovine cholesterol lipoprotein standards (Sigma-Aldrich, St. Louis, MO, USA) 10 ACS Paragon Plus Environment

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were used to calibrate the signal on the basis of peak areas. Fifteen µL of plasma was

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injected via an Agilent 1100 autosampler onto a Superose 6HR HPLC column

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(Pharmacia LKB Biotechnology, Piscataway, NJ, USA). The lipoproteins were eluted

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with a pH 7.0 buffer solution containing 0.15 M sodium chloride and 0.02% sodium

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azide at a flow rate of 0.5 mL/min. Plasma lipoprotein concentration was calculated

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based on a standard curve.

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Hepatic lipid extraction. The lipid extraction method was modified from Folch

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method (Ametaj, Bobe, Lu, Young, & Beitz, 2003; Folch, Lees, & Sloane Stanley, 1957).

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Frozen liver (10 mg) was minced and transferred into a test tube, 600 µL of

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chloroform/methanol (2:1, v/v) was then added, followed by homogenization at 6500 rpm

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for 10 s. Samples were then centrifuged at 14,000 rpm for 10 min. After centrifugation,

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300 µL of organic layer were transferred into a clean tube and vacuum dry for 20 min.

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The dried lipid was weighed and redissolved in 200 µL 1× Reaction Buffer (5× Reaction

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buffer: 0.5 M potassium phosphate, pH 7.4, 0.25 M NaCl, 25 mM cholic acid, 0.5%

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Triton. X-100) provided by Amplex Red cholesterol assay kit (Invitrogen, Eugene, OR,

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USA) and used for triacylglycerol and cholesterol analysis as described below.

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Triacylglycerol, total cholesterol and free cholesterol in the liver. Hepatic

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triacylglycerol (TG) was enzymatically determined using commercial kits (Triglyceride-

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SL, Sekisui Diagnostics PEI Inc., Charlottetown, Canada). Total cholesterol and free

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cholesterol were quantified by a fluorometric method using the Amplex red cholesterol

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assay kit (Invitrogen, Carlsbad, CA, USA) following manufacturer’s protocols.

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Fecal cholesterol extraction and analysis. Fecal cholesterol was extracted using a

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modified protocol (Folch, 1957). Fecal samples were collected during the 24 h period on 11 ACS Paragon Plus Environment

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day 56 after initiation of the experiment. The samples were freeze-dried and weighed. A

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dried fecal sample (~10 mg) was homogenized in 200 µL of chloroform/methanol (v/v

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2:1), and vortexed for 2 min. The mixture was then centrifuged for 5 min at 14,000 rpm

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in a microcentrifuge tube. The organic phase was transferred into a new clean tube, then

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vacuum dried. The samples were redissolved in 200 µL 1× reaction buffer (5 × reaction

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buffer: 0.5 M potassium phosphate, pH 7.4, 0.25 M NaCl, 25 mM cholic acid, 0.5%

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Triton X-100). The fecal cholesterol content was quantified by a fluorometric method

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using a commercial kit (Amplex red cholesterol assay kit, Invitrogen, NY. USA)

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following the manufacturer’s protocol.

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Fecal bile acid extraction and analysis. Fecal samples collected during the 24 h

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period on day 56 after initiation of the experiment were lyophilized, pulverized, and

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weighed. Twenty mg fecal powder was hydrolyzed in 0.5 mL of 2 M KOH at 50 °C for 5

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hours. The cooled mixture was then extracted with two 3 mL portions of diethyl ether to

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remove non-saponifiable components. Sodium chloride (0.5 mL, 20%) followed by

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hydrochloric acid (0.1 mL, 12 M) were then added to the mixture. Acidified mixture was

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extracted with two portions of 6 mL diethyl ether, evaporated under nitrogen, and

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redissolved in 0.5 mL pure ethanol. Bile acid concentration was measured using a

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commercial kit (Total Bile Acid Assays, Cell Biolabs, Inc., San Diego, CA) following the

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manufacturer’s protocol.

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Total RNA isolation, cDNA synthesis and gene expression analysis from liver and

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adipose tissue. To determine changes in the gene expression, liver were cut into 0.1 to 0.2

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g pieces and homogenized using a Precellys 24 by Bertin Technologies (Villeurbanne,

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France). The RNeasy Mini Kit from Qiagen (Valencia, CA, USA) was used for total 12 ACS Paragon Plus Environment

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RNA isolation for the liver. AffinityScript cDNA Synthesis Kit from Agilent

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Technologies (Santa Clara, CA, USA) was used to reverse transcribe complementary

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DNA. Real-time PCR was performed using the TaqMan method as previously reported

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according to the manufacturer’s protocol (Life Technology). Mouse TaqMan gene

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expression assays used in this study were purchased from Life Technology and included:

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Acetyl-CoA Acetyltransferase (ACAT) 1 and 3, Cytochrome p450 7A1 (CYP7A1),

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Diacylglycerol

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Reductase (HMGCR), Lecithin-Cholesterol Acyltransferase (LCAT), LDL receptor

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(LDLR), Sterol O-Acyltransferase 1 (SOAT1), TATA-binding protein (TBP).

O-Acyltransferase

1

(DGAT1),

3-Hydroxy-3-Methylglutaryl-CoA

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Statistical analysis. All end point assays for each sample were conducted in

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triplicate, and the average was used for group analysis. Data for each treatment group

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were presented as mean ± SEM. Statistics analysis was performed using GraphPad Prism

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6 (2012, GraphPad Software, La Jolla, CA, USA). A significant level of differences in

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the means was detected using one-way ANOVA follow by Fisher’s PLSD post hoc test.

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Statistical significance was defined at p ≤ 0.05.

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RESULTS

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Comparison of phytochemical composition in mature red cabbage and red cabbage

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microgreen.

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Major purported bioactive components, anthocyanin, polyphenols, and glucosinolates, in

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mature red cabbage and red cabbage microgreen were compared 20-22. Total anthocyanin

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concentration was determined to be 12.44 µmol/g dry weight in MG, and 33.36 µmol/g

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dry weight in RC. Cyanidin 3-(sinapoyl)(sinapoyl)sophoroside-5-glucoside was the most

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abundant anthocyanin in MG, followed by cyanidin 3-diferuloylsophoroside-5-glucoside

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and cyanidin 3-(feruloyl)sophoroside-5-glucoside. By contrast, the major RC anthocyanin

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is cyanidin 3-(feruloyl)sophoroside-5-glucoside (Table 2A). Concentrations of other

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polyphenols range from 58.57 µmol/g dry weight in MG to 17.22 µmol/g dry weight in

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RC

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trisinapoylgentionbiose are the top 3 polyphenols in MG. Kaempferol acyl-glucoside

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being the major polyphenol in RC (Table 2B) (Supplemental Fig. 1-3). Progoitrin and

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sinigrin were the most abundant GLs in both MG and RC. However, MG contains 3× and

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4× more progoitrin and sinigrin per gram dry weight than that in RC, respectively.

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Overall, MG (17.15 µmol/g) contained two folds more GLs than that in RC (8.30

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µmol/g).

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Effects of Red Cabbage Microgreen on Food Intake and Body Weight Gain

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There were no significant differences in food intake amongst the diet treatments (Fig. 2A).

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For all diet groups, body weights continued to increase through the end of the experiment

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(week 8). Body weights were significantly increased in animals fed the HF diet,

was

detected.

Sinapoyl-hexose,

disinapoylgentiobiose,

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1,2,2'-

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compared to LF diet group, beginning on week 5. Weight gain in animals fed HFMG and

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HFRC was significantly less than HF fed animals (Fig. 2B). Interestingly, the rate of

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body weight gain appeared to be higher for LFMG and LFRC, when compared to the LF

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control.

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Effect of Red Cabbage Microgreen on Plasma Lipoprotein Levels

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Compared to the animals on LF diet, low-density lipoprotein (LDL) (166%), and high-

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density lipoprotein (HDL) (27%) were significantly higher in HF-diet fed group (Fig. 3).

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Animals on the HFMG diet showed significantly lower LDL than the HF diet group,

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while HFRC has significantly lower HDL than the HF group. There were no differences

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in VLDL between the groups. Animals fed the LFRC diet also had significantly elevated

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LDL (56%) when compared to those of the LF diet group.

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Effects of Red Cabbage Microgreen on Liver Cholesterol and Lipid Content

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There were no differences in hepatic cholesterol content between LF- and HF-fed animals

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(Fig. 4A, B, C). HF-diet-fed animals had significantly higher hepatic TG than those of

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LF-fed animals (Fig. 4D). HFRC-fed animals had significantly lower total hepatic

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cholesterol than those of HF-fed animals, with a trend for lower total hepatic cholesterol

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in the HFMG vs. the HF (p = 0.098) (Fig. 4A). Similarly, LFMG and LFRC also had a

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trend of slightly lower total hepatic cholesterol than LF with p values of 0.096 and 0.073,

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respectively (Fig. 4A). Both HFMG and HFRC group had significantly lower hepatic

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cholesterol ester levels than those of HF-fed animals (Fig. 4B). No differences were

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observed in hepatic free cholesterols among any of the diet groups (Fig. 4C).

308

Additionally, HFMG but not HFRC had significantly lower hepatic TG levels than those 15 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

309

of HF diet animals (Fig. 4D). However, LFRC group has significantly higher TG than LF

310

group (Fig. 4D).

311

Effects of Red Cabbage Microgreen on Fecal Bile Acid and Cholesterol Content.

312

Compared to the LF diet group, animals fed the HF diet excreted more bile acids in their

313

feces (55%) (Fig. 5A). However, neither MG nor RC supplements affected bile acid level

314

in their respective LF and HF diet groups (Fig. 5A). HF diet group excreted significantly

315

more cholesterol than animals fed LF diet (177%) (Fig. 5B). HFRC fed animals showed

316

reduced total fecal cholesterol (32%) when compared to animals in the HF diet group

317

(Fig. 5B).

318

Effects of Red Cabbage Microgreens on Genes Associated with Cholesterol and

319

Triacylglycerol Metabolism in Liver.

320

Transcriptional regulation of cholesterol and triacylglycerol metabolism-related genes

321

were examined as it correlates to the biochemical analyses to elucidate potential

322

mechanisms. Feeding an HF diet significantly up-regulated bile acid synthesis enzyme

323

CYP7A1, which is the rate-limiting step for cholesterol removal 23, 24, compared to the LF

324

diet group (Fig. 6A). No differences were observed on the expression of CYP7A1 in any

325

of the MG- or RC-supplemented diet groups with the HF or LF control diets. We also did

326

not observe an effect of MG or RC-supplementation on the cholesterol pathway enzyme,

327

HMGCR, or LDLR (data not shown). An animal fed the HF diet had increased

328

expression of ACAT1 and ACAT3 (Figure 6 B, C), enzymes involved in fatty acid

329

oxidation. HFMG- and HFRC-fed animals had significantly reduced expression of

330

ACAT1 and ACAT3 (Fig. 6B, C). No effects were observed for ACAT2 in any of the 16 ACS Paragon Plus Environment

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331

diet groups (data not shown). HFMG fed animals also had significantly lower SOAT1

332

mRNA level, an enzyme involved in cholesterol ester synthesis, than the HF-fed animals

333

(Figure 6D). HFMG fed animals had significantly lower mRNA levels for a gene

334

necessary for storage of triacylglycerols, DGAT1, than those of the HF-fed animals (Fig.

335

6E). Both MG and RC supplementation in the HF diet significantly lowered mRNA

336

levels of the lipoprotein synthetic enzyme, LCAT (Fig. 6F).

337

Effects of Red Cabbage Microgreen on Inflammatory Markers in the Liver.

338

Consuming HF diets can lead to hepatic inflammation

339

hepatic inflammatory markers was also analyzed. CRP and TNF-α expression levels were

340

shown to be elevated in the livers of the HF diet group compared to those of the LF diet

341

group (Fig. 6G, H). Animals supplemented with MG and RC had significantly lower CRP

342

and TNF-α mRNA levels (Fig. 6G, H). IL-6 mRNA was also analyzed but was not

343

detectable in any group under the same assay condition.

25, 26

344

17 ACS Paragon Plus Environment

. Therefore, expression of

Journal of Agricultural and Food Chemistry

345

DISCUSSION

346

This is the first report evaluating the potential health promoting properties of RCMG in a

347

rodent model. We observed a 1.09% RCMG supplementation in a high fat diet for eight

348

weeks attenuated body weight compared to the HF diet control. Elevated circulating LDL

349

is a known risk factor for CVD

350

profiles in blood by lowering LDL levels induced by high-fat diet and thus may reduce

351

the risk of CVD. High fat diet induced hypercholesterolemia and chronic inflammation

352

are also associated with the development of several chronic diseases, such as CVD,

353

obesity, cancer, etc.

354

hepatic cholesterol ester, triacylglycerol levels and expression of inflammatory cytokines

355

(CRP and TNF-α). Hence, the improvements in CVD risk parameters from microgreen

356

supplementation are consistent with the generally health promoting effects for RCMG.

357

Compared to the mature RC counterpart, the RCMG shared similarity as well as

358

differences in biological effects. Both RCMG and RC lowered body weight gain, hepatic

359

cholesterol, and expression of inflammatory markers induced by HF diets. HFRC- but not

360

HFMG-fed animals had significantly lower fecal cholesterol excretion, however, the

361

exact mechanism was not clear. Intestinal cholesterol excretion or gut microbiota may

362

play a role in the altered fecal cholesterol excretion, and further study is warranted to

363

elucidate the underlying mechanism. HFMG- but not HFRC-fed animals had

364

significantly lower plasma LDL and hepatic TG levels than those of the HF-fed animals.

365

These results suggest that RC and RCMG share general health promoting effects,

366

although the underlying mechanisms may differ. This notion is further supported, at the

367

molecular level, by the differential effects on gene expression of cholesterol and

15, 27

. Supplementation of RCMG improved lipoprotein

28-30

. Animals fed RCMG-supplemented diets showed reductions in

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368

triacylglycerols metabolism enzymes in the liver. RCMG but not RC affected the

369

cholesterol ester synthesis enzyme SOAT1, which is consistent with the cholesterol ester

370

lowering effect of RCMG observed in the HF-fed animals. The triacylglycerol synthesis

371

enzyme DGAT1

372

terminal and only committed step in triacylglycerol synthesis by using diacylglycerol and

373

fatty acyl CoA as substrates

374

triacylglycerol-lowering effects in the liver of RCMG but not RC.

375

ACAT1, a mitochondrial enzyme that catalyzes the reversible conversion of two

376

molecules

377

oxidation/degradation pathway 33, 34. Consuming an HF diet induces this enzyme and is

378

consistent with the animal’s response to the HF diet by increasing fatty acid oxidation.

379

Both RCMG and RC supplementation led to attenuation of HF diet-induced increases in

380

ACAT1. The result may be a reflection of the overall effect of RCMG and RC on overall

381

lipid metabolisms altered by HF diet. How RCMG or RC may directly regulate ACAT1

382

or reduce the effect of HF remain unclear and further study is necessary to elucidate the

383

specific mechanisms.

384

Both RC and RCMG consumption led to lower LCAT expression in the liver as

385

compared to their respective controls. LCAT is known to be involved in extracellular

386

cholesterol esterification and cholesterol transport

387

with small but significant decreases in HDL levels in HFRC group and the decrease in

388

LDL levels in the HFMG group compared to those of the HF group. However, change in

389

LCAT also occurred in LFRC and LFMG groups relative to the LF diet group suggesting

390

dietary component(s) from RCMG and RC may play a role in the regulation of hepatic

of

31, 32

was down-regulated by RCMG but not RC. DGAT1 catalyzes the

acetyl-CoA

31

. Downregulation of DGAT1 is consistent with the

to

acetoacetyl-CoA,

35

is

involved

in

the

fatty

. Lowering of LCAT is consistent

19 ACS Paragon Plus Environment

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391

LCAT activity. The consequence of the changes in expression remained less clear and

392

warrants further study. Additionally, recent studies suggested that lower LCAT may be

393

associated with an increase in obesity-related insulin sensitivity 36, 37. The effect of RC or

394

RCMG on insulin sensitivity was not examined in this study and warrants further

395

validation.

396

Diets high in fat content are known to induce a variety of physiological changes,

397

including chronic, low-grade inflammation in the liver 26. Our observation of inhibitory

398

effects of RC and RCMG on HF diet-induced increases in CRP and TNF-α expression,

399

inflammatory markers in the liver 38, suggested that supplementation of RC or RCMG in

400

HF diets may help alleviate hepatic inflammation. Therefore, the inclusion of RC or

401

RCMG in the Western style diet may contribute to the prevention of diet-related chronic

402

conditions in the U.S. population.

403

Given that food intake was similar in all groups, the effect on lowering weight gain

404

elicited by RCMG or RC in animals fed the HF diet was unexpected. The mechanism of

405

this novel finding is unclear. Since the movement, activity, and behavior of animals in

406

this study were not specifically monitored, it is possible that altered baseline energy

407

expenditure may be a contributing factor and warrant additional study. One possible

408

regulatory mechanism may involve UCP1 39, a protein involved in energy balance, which

409

is known to be affected by phytochemicals in the diet40-42. Analysis of adipose tissue

410

from different depots and UCP1 expression would be an important next step. The

411

increase in body weight in LFRC and LFMG groups compared to those of the LF group

412

was also unexpected. The animals were transitioning from juvenile to adulthood from the

413

start of the experiment (6 weeks old) toward the end (14 weeks old), so it is possible that 20 ACS Paragon Plus Environment

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414

both RC and RCMG may provide additional components that maximize their growth.

415

Future studies are needed to identify the active components.

416

Polyphenols and glucosinolates are known bioactive compounds in fruits and vegetables,

417

and major phytochemical components in RC.20-22 In this study, RCMG was determined to

418

contain more polyphenols (71.01 µmol/g) and glucosinolates (17.15 µmol/g) than RC

419

(50.58 µmol/g and 8.30 µmol/g, respectively). Polyphenols and glucosinolates have been

420

shown in previous studies to possess cholesterol-lowering,

421

inflammation 47-49 properties. Therefore, it is possible that these bioactive components in

422

RCMG and RC may contribute to the observed differential cholesterol-lowering and anti-

423

inflammation effects in this study. Anthocyanins give a red hue, and consistent with the

424

color differences between RC and RCMG (Fig. 1), RCMG contained about 1/3 of

425

anthocyanin than the RC. Hence, the compositions of RCMG and its mature counterpart

426

are quite different. However, the precise components from RC or RCMG that provide

427

health beneficial effect remain to be elucidated in future studies.

428

In summary, supplementing diets with 1.09% RCMG or 1.66% RC, the equivalence of

429

200 g vegetables/day/person, modulated body weight, plasma lipoprotein profiles, and

430

inflammatory status. In mice fed high fat diets supplementation with RCMG or RC had a

431

beneficial effect against lipid risk factors for the development of CVD. This study also

432

provided the first evidence that RCMG and its mature counterpart may regulate the lipid

433

and cholesterol metabolisms differently. One could speculate that other microgreens may

434

have similar effects, although additional studies are needed. Further delineation of the

435

mechanisms of action is also needed, especially as related to energy expenditure and lipid

436

metabolism. 21 ACS Paragon Plus Environment

43-45

antioxidant,

46

and anti-

Journal of Agricultural and Food Chemistry

437

ACKNOWLEDGMENT

438

The authors thank Dr. Naomi Fukagawa for her comments and suggestion on the

439

manuscript.

440

441

FUNDING SOURCES

442

This work was supported by USDA appropriated fund #8040-51530-056-00D.

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443

FIGURE LEGENDS

444

Figure 1. Red cabbage microgreen and red cabbage photo.

445

Figure 2. Food intake and body weight gain. Animals were divided into six diet groups

446

and fed respective diets for 8 weeks. Food intake and body weight gain were assessed as

447

described in the Materials and Methods. The diet groups were : LF, HF, LFMG, LFRC,

448

HFMG, and HFRC. Panel A. Food intake (g/week). Panel B. Weight gain (g/week).

449

Results are expressed as mean ± SE (n=10/group). Bars with different letters indicate

450

significant difference at p≤0.05.

451

Figure 3. Plasma lipoproteins levels. Animals were divided into six diet groups and fed

452

respective diets for 8 weeks. Plasma HDL, LDL, and VLDL levels measured as described

453

in the Materials and Methods. The diet groups were : LF, HF, LFMG, LFRC, HFMG and

454

HFRC. A. VLDL, B. LDL, C. HDL. Results expressed as mean ± SE (n=10/group). *

455

indicates a significant difference between respective groups at p≤0.05.

456

Figure 4. Liver cholesterol and triacylglycerol levels. Animals were divided into six diet

457

group and fed respective diets for 8 weeks. Liver cholesterol and triacylglycerol levels

458

measured as described in the Materials and Methods. The diet groups were : LF, HF,

459

LFMG, LFRC, HFMG and HFRC. A. Total cholesterol , B. Cholesterol ester, C. Free

460

cholesterol, D. Triacylglycerols. Results expressed as mean ± SE (n=10). * indicates a

461

significant difference between the respective groups at p≤0.05.

462

Figure 5. Fecal bile acid and cholesterol levels. Animals were divided into six diet

463

groups and fed respective diets for 8 weeks. Fecal samples collected on the day of

464

sacrifice and fecal bile acid, cholesterol levels measured as described in the Materials and 23 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

465

Methods. The diet groups were : LF, HF, LFMG, LFRC, HFMG and HFRC. A. Fecal

466

bile acid, B. Fecal total cholesterol. Results expressed as mean ± SE (n=10/group). *

467

indicates a significant difference between the respective groups at p≤0.05.

468

Figure 6. Cholesterol, triacylglycerol metabolism and inflammation-related genes

469

expression levels in liver. Animals were divided into six diet groups and fed respective

470

diets for 8 weeks. Liver samples obtained at the end of 8 weeks. RNA isolated and

471

expression of marker genes assessed using RT-PCR as described in the Materials and

472

Methods. The diet groups were : LF, HF, LFMG, LFRC, HFMG and HFRC. A.

473

CYP7A1 , B. ACAT1, C. ACAT3 , D. SOAT1, E. DGAT1, F. LCAT, G. CRP, H. TNF-

474

α. Results expressed as mean ± SE (n=10/group). * indicates a significant difference

475

between the respective groups at p≤0.05.

476

24 ACS Paragon Plus Environment

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Journal of Agricultural and Food Chemistry

Table 1. Diet composition. Dieta LFa g% kcal% Protein 19 20 Carbohydrate 67 70 Fat 4 10 Total 100 Kcal/g 3.8 Ingredient g kcal Casein 200 800 L-Cystine 3 12 Corn starch 452.2 1809 Maltodextrin 75 300 Sucrose 172.8 691 Cellulose 50 0 Corn oil 25 225 Lard 20 180 Mineral mix 10 0 Dicalcium phosphate 13 0 Calcium carbonate 5.5 0 Potassium citrate 16.5 0 Vitamin mix 10 40 Choline Bitartrate 2 0 b MG powder RC powderb Total 1055 4057

477

478 479 480 481 482

LF + MGa g% kcal% 19 20 67 70 4 10 100 3.8 g kcal 200 800 3 12 452.2 1809 75 300 172.8 691 50 0 25 225 20 180 10 0 13 0 5.5 0 16.5 0 10 40 2 0 11.63 1066.63

4057

LF + RCa g% kcal% 19 20 66 70 4 10 100 3.8 g kcal 200 800 3 12 452.2 1809 75 300 172.8 691 50 0 25 225 20 180 10 0 13 0 5.5 0 16.5 0 10 40 2 0 17.81 1072.81

4057

g% 24 41 24

HFa kcal% 20 35 45 100

4.7 g 200 3 72.8 100 172.8 50 25 177.5 10 13 5.5 16.5 10 2

kcal 800 12 291 400 691 0 225 1598 0 0 0 0 40 0

858.1

4057

a

HF + MGa g% kcal% 23 20 41 35 23 45 100 4.7 g kcal 200 800 3 12 72.8 291 100 400 172.8 691 50 0 25 225 177.5 1598 10 0 13 0 5.5 0 16.5 0 10 40 2 0 9.46 867.56

4057

HF + RCa g% kcal% 23 20 41 35 23 45 100 4.6 g kcal 200 800 3 12 72.8 291 100 400 172.8 691 50 0 25 225 177.5 1598 10 0 13 0 5.5 0 16.5 0 10 40 2 0 14.49 872.59

4057

All the diets used in this animal study were formulated by Research Diet (New Brunswick, NJ, USA). LF, LF + MG, and LF + RC represent low fat diet, low fat diet supplemented with red cabbage microgreens powder, and low fat diet supplemented with mature red cabbage powder, respectively. Similarly, HF, HF + MG and HF + RC represent high fat diet, high fat diet supplemented with red cabbage microgreens powder, and high fat diet supplemented with mature red cabbage powder, respectively. b MG powder is the powder made from lyophilized red cabbage microgreens and RC powder is the powder made from lyophilized mature red cabbage.

25 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Table 2A. Anthocyanin in microgreen and mature red cabbage Red Cabbage Microgreen Tentative Identification µmol/g cyanidin 3-diglucoside-5-glucoside 0.41 cyanidin 3-(sinapoyl)-diglucoside-5-glucosides 1.13 cyanidin 3-(glucosyl)(sinapoyl)(p-coumaroyl)sophorside-5glucoside 0.49 cyanidin 3-(glucosyl)(sinapoyl)(feruloyl)sophorside-5glucoside 0.57 cyanidin 3-diferuloylsophoroside-5-glucoside 0.59 cyanidin 3-(coumaroyl)sophoroside-5-glucoside 0.57 cyanidin 3-(feruloyl)sophoroside-5-glucoside 1.68 cyanidin 3-diferuloylsophoroside-5-glucoside 2.06 cyanidin 3-(sinapoyl)(feruloyl)sophoroside-5-glucoside 1.30 cyanidin 3-(sinapoyl)(sinapoyl)sophoroside-5-glucoside 3.65 Total 12.44 Mature Red Cabbage Tentative Identification µmol/g cyanidin 3-diglucoside-5-glucoside 2.42 cyanidin 3-(sinapoyl)-diglucoside-5-glucosides 0.63 cyanidin 3-(glucosyl)(sinapoyl)(p-coumaroyl)sophorside-5glucoside 0.82 cyanidin-3-(glucosyl)(sinapoyl)(feruloyl)sophorside-5glucoside 1.54 cyanidin 3-(coumaroyl)sophoroside-5-glucoside 0.83 cyanidin 3-diferuloylsophoroside-5-glucoside 1.27 cyanidin 3-(feruloyl)sophoroside-5-glucoside 22.96 cyanidin 3-(sinapoyl)(feruloyl)sophoroside-5-glucoside 0.74 cyanidin 3-(sinapoyl)(sinapoyl)sophoroside-5-glucoside 2.13 Total 33.36 483 484

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Journal of Agricultural and Food Chemistry

Table 2B. Other polyphenols in microgreen and mature red cabbage Red Cabbage Microgreen Tentative Identification µmol/g citric acid 0.27 3-caffeoylquinic acid 2.40 caffeoyl glucose 1.62 hydroxyferuloylglucose 1.59 kaempferol 3-diglucoside 2.80 sinapoyl-hexose 27.80 disinapoylgentiobiose 12.00 1,2,2'-trisinapoylgentionbiose 8.36 unknown 1.72 Total 58.57 Mature Red Cabbage Tentative Identification µmol/g citric acid 0.36 3-caffeoylquinic acid 1.92 sinapoyl-hexose 0.99 kaempferol acyl-glucoside 11.89 kaempferol 3-sinapoylsophoroside-7-glucoside 0.17 kaempferol 3-hydroxyferuloylsophorotrioside-7-glucoside 0.69 kaempferol 3-sinapoylferuloylsophoroside-7-glucoside 0.48 kaempferol 3-disinapoyldiglucoside-7-glucoside 0.07 1,2,2'-trisinapoylgentionbiose 0.27 unknown 0.39 Total 17.22 485 486

27 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

487

Table. 3 PDA response factor of desulfo glucosinolate No. 1 2 3 4 5 6 7 8

Desulfo glucosinolate desulfosinigrin desulfoglucoraphanin Desulfo-4-hydroxyglucobrassicin Other desulfo- hydroxyglucobrassicin Desulfo-glucobrassicin Desulfo-4-methoxyglucobrassicin Other desulfo methoxyglucobrassicin Other glucosinolate

Response factor 1.00 1.07 0.28 0.28 0.20 0.25 0.25 1.00

488 489

Table. 4 Desulfo-glucosinolates in microgreen and mature red cabbage

1 2 3 4 5 6 7 8 9

progoitrin glucoraphanin sinigrin gluconapin 4-hydroxyglucobrassicin glucoerucin glucobrassicin 4-methoxylglucobrassicin neoglucobrassicin Total

Red Cabbage Microgreen (µmol/g dry weight) 6.87 4.80 6.12 1.31 1.96 1.16 1.15 0.51 0.15 17.15

Mature Red Cabbage (µmol/g dry weight) 2.29 0.88 1.53 1.33 0.39 0.37 1.26 0.26 N.D 8.30

490 491

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Journal of Agricultural and Food Chemistry

Figure 1. Red cabbage microgreen and red cabbage.

493

29 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Figure 2. Food intake and body weight gain.

H FR C

G H FM

LF R C

G LF M

H F

LF

Growth rate (g/week)

Food intake (g/week)

494

495 496 497 498 499

30 ACS Paragon Plus Environment

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500

Journal of Agricultural and Food Chemistry

Figure 3. Plasma lipoproteins levels.

A. VLDL 6

VLDL (mg/dl)

5 4

LDL (mg/dl)

LF HF LFMG LFRC HFMG HFRC

3 2 1

Diets

C. HDL

* *

*

140

LF HF LFMG LFRC HFMG HFRC

120 100 80 60 40 20

H FR C

H FM G

LF R C

LF M G

H F

0

LF

Diets

501 502 503

31 ACS Paragon Plus Environment

HF R C

R C

H FM G

LF

M G LF

H F

LF

H FR C

R C

H FM G

LF

M G LF

H F

LF

0

Journal of Agricultural and Food Chemistry

505 506

32 ACS Paragon Plus Environment

C FR FR

C

H

G FM G

H

FM

C H H

LF R R C LF

M G LF

F

G

F H H

LF M

LF LF

C FR H

C FR

FM

FM

G

H

H

H

G

C LF R

RC LF

G LF M

LF

M G

H

H

F

LF

F

Figure 4. Liver cholesterol and triacylglycerol levels.

LF

504

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Page 33 of 41

507

Journal of Agricultural and Food Chemistry

Figure 5. Fecal bile acid and cholesterol levels.

A. Fecal Bile Acid

*

Fecal Bile Acid ( mol CA equiv/mg)

10

LF HF LFMG LFRC HFMG HFRC

8

6

4

2

H FR C

H FM G

LF RC

F H

LF M G

LF

0

Diets

B. Fecal Total Choleterol 2.0

*

Total Cholesterol (µg/mg)

*

LF HF LFMG LFRC HFMG HFRC

1.5

1.0

0.5

H FR C

G H FM

C

F

G

LF R

LF M

H

LF

0.0

Diets

508 509

33 ACS Paragon Plus Environment

Journal of Agricultural and Food Chemistry

Figure 6. Cholesterol and triacylglycerol metabolism and inflammation-related genes expression

511

levels in liver.

C

G

H FR

RC

FM

LF

LF

H

F

G

H

M

LF

G

FR C H

R C

FM

LF

H

F

G M LF

H

LF

Relative mRNA Levels

510

D. SOAT1

*

1.4

*

1.2 1.0 0.8 0.6 0.4 0.2

C F+ R H

G

+R C LF

H

LF

F+ M

G

F H

+M

LF

C

G

HF R

C R LF

H FM

G M LF

LF

H F

0.0

Relative mRNA Levels

*

*

C HF R

FM H

LF

H. TNF-

3.0

G

C R

G

F H

M LF

C

G

HF R

FM

C R LF

H

LF

M

G

F H

LF

LF

Diets

* LF HF LFMG LFRC HFMG HFRC

2.5 2.0 1.5 1.0 0.5

H

FR C H

G FM

RC LF

G

F H

M LF

LF

C

G

H FR

FM

RC LF

H

LF

M

G

F H

LF

0.0

Diets

512 513

34 ACS Paragon Plus Environment

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Journal of Agricultural and Food Chemistry

514

Supplemental information

515

Fig. 1 HPLC chromatogram of microgreen and red cabbage at 330 nm A: MG and B: RC RT: 0.00 - 60.00 NL: 1.02E6 nm=329.5330.5 PDA MG

10.01 1000000

A

900000 800000 700000

23.43

9.90

uAU

600000

26.94

500000 400000 23.06

300000 200000

12.04

100000

1.64 4.39

0 300000

8.83 8.94 7.56

4.63

14.36 17.53

19.72

21.46 20.15

15.21

B

24.89

29.19

32.11 34.16 35.22 37.34 39.44

43.72 45.66 48.35

50.07 51.26

51.52

58.00 NL: 3.01E5 nm=329.5330.5 PDA rc

20.19

250000

200000 13.74

14.71

23.10

150000

100000

19.86 4.64

50000 1.69

5.84

4.42

22.89

10.03 11.45 9.91 8.95

16.00 18.68

26.96

23.44

29.28 30.60

34.37 35.91

0 0

5

10

15

20

25

516 517

30 Time (min)

35

42.65

40.06 40

45.34 47.64 50.06 51.25 45

56.84 59.21

54.21

50

55

Fig. 2 HPLC chromatogram of microgreen and red cabbage at 520 nm A: MG and B: RC RT: 0.00 - 60.00 NL: 2.19E5 nm=519.5520.5 PDA MG

23.06

A

200000 180000 160000

uAU

140000 120000 100000

22.47

80000 60000 20.27

40000 11.33 20000 1.84 2.26 4.47

0

7.57

10.33

18.30

12.80

46.72 48.35 50.06 51.26

18.69 23.52

34.05 35.98 37.31 40.22 42.43 44.84 46.30

25.24

NL: 4.31E5 nm=519.5520.5 PDA rc

20.19

400000

B

350000 300000 250000 200000 19.85

150000

23.10

100000

28.68 30.61 1.77

5.12 6.84

34.23 35.91

59.21

22.50

7.58

50000

10.41

11.34

15.47

16.02

27.77

18.67

33.88

37.65

41.65 42.50 43.02

45.49

50.06

52.61 54.47 57.01

58.62

0 0

5

10

15

20

25

30 Time (min)

518

35

519 35 ACS Paragon Plus Environment

40

45

50

55

60

60

Journal of Agricultural and Food Chemistry

520

Page 36 of 41

Fig. 3 The HPLC chromatogram of desulfo glucosinolates in A: MG and B: RC

RT: 1.06 - 19.28 160000 150000

NL: 1.64E5 Channel A UV RCMG1A

A

140000 130000 120000 110000 100000

uAU

90000 80000 70000 60000 50000 40000 30000 20000 10000 0 2

3

4

5

6

7

8

9

10 Time (min)

521 522

11

12

13

14

15

16

17

18

19

RT: 0.11 - 19.41

110000

NL: 1.26E5 Channel A UV RCVP1A

B

100000 90000 80000 70000

uAU

60000 50000 40000 30000 20000 10000 0 -10000 1

2

3

4

5

6

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