Christian D. Mitchell scite author profile

The genomes of most vertebrates contain many V, D, and J gene segments within their Ig loci to construct highly variable CDR3 sequences through combinatorial diversity. This nucleotide variability translates into an antibody population containing extensive paratope diversity. Cattle have relatively few functional VDJ gene segments, requiring innovative approaches for generating diversity like the use of ultralong-encoding IGHV and IGHD gene segments that yield dramatically elongated CDR H3. Unique knob and stalk microdomains create protracted paratopes, where the antigen-binding knob sits atop a long stalk, allowing the antibody to bind both surface and recessed antigen epitopes. We examined genomes of twelve species of Bovidae to determine when ultralong-encoding IGHV and IGHD gene segments evolved. We located the 8-bp duplication encoding the unique TTVHQ motif in ultralong IGHV segments in six Bovid species (cattle, zebu, wild yak, domestic yak, American bison, and domestic gayal), but we did not find evidence of the duplication in species beyond the Bos and Bison genera. Additionally, we analyzed mRNA from bison spleen and identified a rich repertoire of expressed ultralong CDR H3 antibody mRNA, suggesting that bison use ultralong IGHV transcripts in their host defense. We found ultralong-encoding IGHD gene segments in all the same species except domestic yak, but again not beyond the Bos and Bison clade. Thus, the duplication event leading to this ultralong-encoding IGHV gene segment and the emergence of the ultralong-encoding IGHD gene segment appears to have evolved in a common ancestor of the Bos and Bison genera 5–10 million years ago. Supplementary Information The online version contains supplementary material available at 10.1007/s00251-023-01305-9.

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Evolution of immunogenetic components used to form ultralong VH CDR3 antibodies in Bovidae

Mitchell

Marchand

Head

et al. 2021

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Cattle has a restricted repository of immunoglobulin heavy chain gene segments with only one family of V, 4 J and 16 D segments functional. Among these segments are a V and D that, together, encode a heavy chain with an ultralong CDR3 region which manifests as a “stalk” supporting a “knob” domain of which only the knob has antigen binding capability. This antibody structure has boundless therapeutic potential, including for treatment of HIV and other antigens with veiled epitopes. Upon the discovery of this ultralong antibody in Bos taurus, speculation of its origin began. The components that should facilitate ultralong CDR3H antibodies appear in more species than just Bos taurus; they expand throughout the bovine subfamily as evidence by the presence of a V motif “TTVHQ” crested by an 8 base-pair (bp) duplication, and a comparatively long D segment. Several closely-related species encode the ultralong V segments gene in their germline IgH locus. Phylogenetically bookending the cluster that is genomically equipped for the ultralong cattlebody are the species Bos taurus and Bison bison with Bos mutus, indicus, and grunniens in between. The added length of the D segment is less consistent throughout the group as none of the species encode as long of segment as Bos taurus at 50 amino acids. Two species studied, Bos mutus and Bos grunniens, have 15 and 22 amino acids, respectively, encoded by their longest D segment, and Bison bison has 23. Though we do know the germline encodes the ultralong antibody, it is imperative to know if the gene rearrangement is actually expressed and employed in the mature repertoire.

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Implementing a Hybrid Expression Method That Allows Upper-Division Biochemistry Lab Students To Engage in a Full Protein Production Experience While Allowing Ample Time for Characterization Experiments

et al. 2019

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Protein structure, function, and signaling are a large portion of biochemistry. Because of this, proteins are often used as model systems in biochemistry laboratory courses, where a course-long project might comprise protein expression, purification, and characterization. Two common protein expression methods are isopropyl β-d-1-thiogalactopyranoside (IPTG) induction, which utilizes easy-to-make media but requires extensive cell-growth monitoring that is time-intensive, and autoinduction, which employs multicomponent media that are time-consuming to make but require no cell-growth monitoring. A protein expression method that is a hybrid of IPTG induction and autoinduction is presented. The hybrid method utilizes the medium of IPTG induction and the no-cell-growth-monitoring induction process of autoinduction, saving hands-on time in the protein expression phase to allow more time for protein characterization while still having students execute each step.

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