Darlene L. Middleton

Enhanced Bacterial Disease Resistance of Transgenic Channel Catfish Ictalurus punctatus Possessing Cecropin Genes

The cecropin B gene from the moth Hyalophora cecropia, driven by the cytomegalovirus promoter, was transferred to the channel catfish Ictalurus punctatus. Transgenic individuals (P1) were mated to produce individuals (F1) that exhibited enhanced disease resistance and survival when challenged with pathogenic bacteria. During the epizootic of Flavobacterium columnare in an earthen pond, the percentage of transgenic individuals containing preprocecropin B construct that survived (100%) was significantly greater (P <0.005) THAN THAT OF NONTRANSGENIC CONTROLS (27.3%). ALSO, WHEN CHALLENGED IN TANKS WITH EDWARDSIELLA ICTALURI, THE CAUSATIVE AGENT OF ENTERIC SEPTICEMIA OF CATFISH, THE PERCENTAGE OF TRANSGENIC INDIVIDUALS CONTAINING CATFISH IG LEADER CECROPIN B CONSTRUCT THAT SURVIVED (40.7%) WAS SIGNIFICANTLY GREATER (P <0.01) THAN THAT OF NONTRANSGENIC CONTROLS (14.8%). THERE WERE NO PLEIOTROPIC EFFECTS OF THE TRANSGENES, AND GROWTH RATES OF THE TRANSGENIC AND NONTRANSGENIC SIBLINGS WERE NOT DIFFERENT (P > 0.05). Inheritance of the transgene by the F1 generation, 20.2% to 30.7% was typical of that in studies with transgenic channel catfish.

cDNA sequences and organization of IgM heavy chain genes in two holostean fish

Immunoglobulin M heavy chain (mu) sequences of two holostean fish, the bowfin, Amia calva, and the longnose gar, Lepisosteus osseus, were amplified from spleen mRNA by RACE-PCR, cloned, and sequenced. Each mu chain showed the conserved four constant domain structure typical of a secreted mu chain. Southern blot analyses with specific heavy chain variable (VH) and constant (CH) region probes suggest that both fish possess an IgH locus that resembles that of the teleosts, amphibians, and mammals in its organization. The overall sequence similarity of gar and bowfin mu chains was 60% and 48% at the nucleotide and amino acid levels, respectively, while similarity to the mu chains of teleosts and elasmobranchs was lower. The bowfin mu chain possesses a distinctive proline-rich sequence at the C mu 1/C mu 2 boundary; a shorter proline-rich sequence is present at this position in the gar mu chain. Both gar and bowfin show, in their C mu 4 sequences, motifs that could serve as cryptic splice donor sites for the production of mRNA encoding the membrane-bound form of the mu chains, and the bowfin also shows a potential cryptic splice donor site in the C mu 3 exon.

Secretory immune system of the duck ( Anas platyrhynchos ). Identification and expression of the genes encoding IgA and IgM heavy chains

IgA has not previously been identified in waterfowl. Studies instead revealed physical and antigenic similarities between duck bile immunoglobulin (Ig) and serum IgM. Here, a differential screening approach was used to clone, from a duck spleen library, the cDNA encoding the heavy (H) chains of IgM and the Ig, identified here as IgA, occurring in duck secretions. Phylogenetic comparisons of inferred amino acid sequences of entire H chain constant (C) regions and of individual domains revealed that the duck μ chain was closest to chicken μ (54 % overall identity), and duck α was closest to chicken α (50 % identity). Comparison of the μ and α C regions revealed areas of up to 65 % amino acid similarity within the C4 domains, accounting for the previously noted antigenic overlap of duck IgM and IgA. Messages for α and μ were detected in duck lymphoid organs but the α message was most abundant in the respiratory, alimentary and reproductive tracts. The α message first appeared around 14 days of age and reached adult levels of expression only at 35 – 50 days. The results indicate that the duck has a mucosal immune system which utilizes IgA; however, the delayed expression and secretion of duck IgA explains the susceptibility of ducklings to mucosal pathogens. Since the waterfowl are among the most primitive extant birds, the recognition of IgA in the duck supports the conclusion that IgA occurs throughout the class Aves and also existed in the common ancestors of birds and mammals.

cDNA sequence and organization of the immunoglobulin light chain gene of the duck, Anas platyrhynchos.

A cDNA was cloned which encoded an immunoglobulin (Ig) light (L) chain of the White Pekin duck. The organization of the variable (V) and constant (C) domains was analyzed by genomic Southern blotting. The duck L chain gene has a similar chromosomal organization to that of the chicken, with a single lambda-like C region and multiple VL, hybridizing elements. The amino acid sequence of the VL region of the White Pekin duck L chain showed 88% identity with the Muscovy duck and 87% identity with the chicken, the JL region showed 92% identity with these species, and the CL region showed 88% identity with Muscovy duck and 66% with chicken. The constraints imposed by the gene-conversion mechanism of generating antibody diversity might account for the similarities of the avian V region sequences.

Functional motifs in the IgH enhancer of the channel catfish

Abstract The transcriptional enhancer (Eμ3′) within the Ig heavy chain (IgH) locus of the channel catfish differs from those found in mammalian IgH loci in both its location and structure. However, upon transfection into fish or mouse lymphocytes, it activates transcription to an extent equivalent to that of the mouse IgH intronic enhancer (Eμ). Potential transcription factor binding motifs in Eμ3′ are more numerous than in mammalian IgH enhancers, and are dispersed over 1.6 kilobases. We transfected catfish and mouse lymphoid cells with reporters under the control of artificial promoters containing motifs from the catfish enhancer. We demonstrate that 9 of 11 octamer motifs identified in the catfish enhancer, representing five variations of the consensus octamer (ATGCAAAT), are functional in both a catfish B-cell line (1B10) and the mouse plasmacytoma J558L. Only those octamer variants in which one of the first four bases is altered are active. Clear species differences in the strengths of the variant octamer motifs were evident, and in catfish B cells the ATGtAAAT motif was over threefold more active than the consensus octamer. The one μA and two μB motifs in Eμ3′ do not contribute to transcriptional activation. These results suggest that the relative functional contributions of IgH enhancer motifs has changed significantly during vertebrate evolution.

An additional family of VH sequences in the channel catfish.

A heavy chain variable region cDNA sequence of the channel catfish (Ictalurus punctatus) prototypical for a new VH family (approximately 20 or more members) is presented. The nucleotide and inferred amino acid sequences differ by 32–52% and 41–68%, respectively, from those for the already described catfish VH families.

Evolution of Transcriptional Control of the IgH Locus: Characterization, Expression, and Function of TF12/HEB Homologs of the Catfish

The transcriptional enhancer (Eμ3′) of the IgH locus of the channel catfish, Ictalurus punctatus, differs from enhancers of the mammalian IgH locus in terms of its position, structure, and function. Transcription factors binding to multiple octamer motifs and a single μE5 motif (an E-box site, consensus CANNTG) interact for its function. E-box binding transcription factors of the class I basic helix-loop-helix family were cloned from a catfish B cell cDNA library in this study, and homologs of TF12/HEB were identified as the most highly represented E-proteins. Two alternatively spliced forms of catfish TF12 (termed CFEB1 and -2) were identified and contained regions homologous to the basic helix-loop-helix and activation domains of other vertebrate E-proteins. CFEB message is widely expressed, with CFEB1 message predominating over that of CFEB2. Both CFEB1 and -2 strongly activated transcription from a μE5-dependent artificial promoter. In catfish B cells, CFEB1 and -2 also activated transcription from the core region of the catfish IgH enhancer (Eμ3′) in a manner dependent on the presence of the μE5 site. Both CFEB1 and -2 bound the μE5 motif, and formed both homo- and heterodimers. CFEB1 and -2 were weakly active or inactive (in a promoter-dependent fashion) in mammalian B-lineage cells. Although E-proteins have been highly conserved in vertebrate evolution, the present results indicate that, at the phylogenetic level of a teleost fish, the TF12/HEB homolog differs from that of mammals in terms of 1) its high level of expression and 2) the presence of isoforms generated by alternative RNA processing.

Expression of a mouse-channel catfish chimeric IgM molecule in a mouse myeloma cell

Fusion genes encoding a murine VH domain and the constant region domains of the mu chain from the channel catfish, Ictalurus punctatus, were stably expressed in the lambda light chain producing mouse myeloma cell line J558L. Although the pathways of pre-mRNA processing for expression of membrane (micron and secreted (microsecond) forms of the mu chain differ between mammals and teleosts, mRNAs encoding both catfish micron and microsecond were correctly expressed in the mouse myeloma cells. The mouse-channel catfish chimeric mu chain polypeptide was able to associate covalently with the mouse lambda light chain and assemble, intracellularly, into polymers of covalent structure (microL)2-8 which resembled those seen with native catfish IgM. In contrast to native catfish IgM, the mouse-catfish chimeric IgM showed the property of binding strongly to protein A of Staphylococcus aureus. The mouse-channel catfish chimeric IgM was core-glycosylated, but did not contain terminal sialic acid. Secretion rates for the chimeric IgM were low, and the possibility could not be excluded that extracellular chimeric IgM was released from dead or dying cells. The reason(s) for the intracellular retention of the chimeric IgM (probably in the endoplasmic reticulum) are not known, but those mechanisms involving retention via cysteine residues were excluded.

Regulation of immunoglobulin gene transcription in a teleost fish: identification, expression and functional properties of E2A in the channel catfish

The function of the transcriptional enhancer, Eμ3′, of the IgH locus of the channel catfish, Ictalurus punctatus, involves the interaction of E-protein and Oct family transcription factors. The E-proteins [class I basic helix–loop–helix (bHLH) family] are encoded in mammals by three genes: E2A (of which E12/E47 are alternatively spliced products), HEB, and E2-2. An E2A homologue has been identified in a catfish B-cell cDNA library and contains regions homologous to the bHLH and activation domains of mammalian and other vertebrate E2A proteins. E2A message is widely expressed, being readily detected in catfish B cells, T cells, kidney, spleen, brain, and muscle. Its expression is lower than that previously observed for TF12/CFEB, the catfish homologue of HEB. E2A strongly activated transcription of a μE5 motif-dependent construct in catfish B cells, and also activated transcription from the core region of the catfish IgH enhancer (Eμ3′) in a manner dependent on the presence of the μE5 site. Catfish E2A, expressed in vitro, bound the μE5 motif present in the core region of Eμ3′. These results document the conservation of structure and function in vertebrate E2A and suggest a potential role of E2A in driving expression of the IgH locus at the phylogenetic level of a teleost fish.

Oct2 transcription factor of a teleost fish: activation domains and function from an enhancer

Oct2 transcription factors of the catfish (Ictalurus punctatus) are expressed as alternatively spliced alpha and beta isoforms. Functional analysis revealed an N-terminal glutamine (Q)-rich transactivation domain common to both isoforms of catfish Oct2. A C-terminal proline, serine, threonine (PST)-rich activation domain was identified exclusively in the beta isoform. Activation domains of fish and mammalian Oct2 showed cell type- and species-specific activity correlated with their biochemical composition (Q-rich vs PST-rich). In contrast the activation domains of the aryl hydrocarbon receptor and aryl hydrocarbon receptor nuclear translocator of fish and mammals showed no correlation of activity with biochemical composition or species of origin. Although isolated catfish Oct2 activation domains were unable to drive transcription from a site 1.9kb distal to the promoter, Oct2beta activated transcription from both an IgH enhancer and an array of octamer motifs at this distal position. The properties of catfish Oct2 activation domains differ depending on whether they are studied in isolation or as components of the intact transcription factor.