Research Summary - 2

Network analysis of splenic gene expression of cattle co-infected with Bovine viral diarrhea virus 2 and Bovine herpes virus 1 following vaccination and trace mineral administration

Date/Time: 9/13/2024    16:30
Author: Matthew A Scott
Clinic: Texas A&M University
City, State, ZIP: Canyon, TX  79015

Matthew A. Scott, DVM, PhD 1 ; Roberto A. Palomares, DVM, MS, PhD, DACT 2 ; M'Lehne K. Linson, BS 3 ; Erika G. Altamiranda, DVM, PhD 4 ; Alejandro Hoyos-Jaramillo, DVM, PhD 2 ; Joao H. Bittar, DVM, MS, PhD 5 ; Adriana Rodriguez, MS, PhD 2 ; Jose Urdaneta, PhD 2 ;
1Veterinary Education, Research, and Outreach Program, College of Veterinary Medicine and Biomedical Sciences, Texas A&M University 79015
2Group for Reproduction in Animals Vaccinology & Infectious Diseases (GRAVID), Department of Population Health, College of Veterinary Medicine, University of Georgia. Athens GA
3Department of Agricultural Sciences, College of Agriculture and Natural Sciences, West Texas A&M University, Canyon, TX 79016
4Consejo Nacional de Investigaciones Científicas y Tecnicas (CONICET), Instituto Nacional de Tecnología Agropecuaria (INTA EEA Balcarce), Buenos Aires, Argentina
5Department of Large Animal Clinical Sciences, College of Veterinary Medicine, University of Florida, Gainesville, FL 32610

Introduction:

A common management practice to prevent bovine respiratory disease (BRD) in dairy and beef cattle often involve the administration of modified-live virus (MLV) vaccines. In addition, injectable trace minerals (ITM) concomitant with vaccination has been associated with an improved immune response and protection elicited by vaccine antigens. While widely utilized, the influence these tools have on immunomodulation and cellular mobilization within central lymphoid tissue is largely unknown. To our knowledge, this study is the first to comprehensively evaluate gene expression patterns from cattle administered MLV vaccines and ITM followed by BVDV2 and BHV1 challenge.

Materials and methods:

A total of 29 male dairy calves (age: ~1 mo) previously enrolled in a larger randomized clinical trial were utilized. Twenty-two calves received an MLV intranasal (IN) vaccine containing BHV1, BRSV, and BPI3V and subcutaneous (SC) ITM (Se, Cu, Zn & Mn; ITM, n = 12) or saline (SAL, n = 10). Ten weeks later, calves received a second dose of ITM, or saline, according to previous groups and were randomly assigned to receive the same IN vaccine [ITM-IN (n = 6), SAL-IN (n = 5)] or a SC MLV vaccine containing BHV1, BRSV, BPI3V, BVDV1 & 2 [ITM-SC (n = 6), SAL-SC (n = 5)]. Seven calves did not receive vaccine or treatment and served as a control group (UNVAC, n = 7). Forty-nine days after booster, all calves were challenged with BVDV2; and seven days later with BHV1. Calves were euthanized seven days after BHV1 challenge and lymphoid tissues including spleen were preserved in RNA later and stored at -80 ͦ C until processing. Total RNA was extracted from spleen samples using RNeasy Mini Kits (Qiagen®) according to manufacturer instructions. RNA sequencing (NovaSeq 6000; ~47M PE reads/sample) was performed from isolated splenic RNA. Following HISAT2-StringTie2 reference-guided gene assembly, weighted gene co-expression network analysis (WGCNA) was utilized for expression network and gene module construction. Filtered genes (n=15,130) were constructed into co-expression modules according to signed biweight midcorrelation, with a minimum of 40 genes in each module, merging modules with intermodular correlations above 0.70, and assigning unique color identifications to each expression module. Module-trait Kendall’s tau coefficients were identified between gene expression modules and clinical traits, further considered as weak or strong at p<0.1 and |R|>0.20 or p<0.05 and |R|>0.30, respectively. Significantly correlated modules were evaluated for functional enrichments via over-representation analysis within g:Profiler (FDR<0.05). Hub genes (|R|>0.30) driving correlations with clinical illness scores were evaluated for predicted protein-protein interactions via STRING v12.0 (confidence score>0.500).

Results:

One expression module (“yellow”) was positively associated with vaccination; this module possessed genes related to cellular filament organization and development, Notch signaling, extracellular kinase cascade, and collagen biosynthesis. One expression module (“purple”) was negatively associated with trace minerals administration; this module possessed genes related to the regulation of T-cell activation, antigen processing and presentation via MHC class II, complement regulation, interferon-γ signaling, and neutrophil degranulation. Four expression modules (“brown”, “green”, “turquoise”, “blue”) were associated with clinical illness scores over time; gene products from these modules formed a predicted protein-protein interaction complex centered around ubiquitin C.

Significance:

These results illustrate associations between central lymphoid gene expression patterns following BVDV2 and BHV1 infections and two significant management practices (vaccination and trace mineral administration) used to control BRD. These patterns may be leveraged to improve our understanding of immunomodulation and acquired immune response against viral infections involved in BRD.