The diversity of connexin genes encoding gap junctional proteins.

The multigene family of connexins is larger than previously anticipated. Ten different connexin homologous sequences have been characterized in the mouse genome, five of which are probably the mouse analogues of the known rat connexins26, -31, -32, -43, and -46. Since the additional 5 sequences have been isolated as cDNAs or hybridize specifically to distinct mRNA species, they most likely represent functional connexin genes. Since seven of the genomic connexin sequences have been shown to contain no intron in the coding sequence, this may apply to all mammalian connexin genes. Some of the structural features based on amino acid sequences deduced from cDNA or genomic sequences and the RNA expression pattern of the new connexins are compared with previously described connexins. The structural diversity of the connexin genes suggests that they fulfill different functions coordinated with, and perhaps required for, different programs of cellular differentiation.

Mouse connexin37: cloning and functional expression of a gap junction gene highly expressed in lung.

The coding sequence (333 amino acids) of a new connexin protein, designated mouse connexin37 (Cx37 or Cx37.6) due to the deduced theoretical molecular mass of 37.600 kD, has been determined from cDNA and genomic clones. As seen in other connexins, its gene has no introns within the coding region and the deduced amino acid sequence is predicted to have similar topology to other connexins that form intercellular channels. The amino acid sequence of mouse Cx37 is most similar to rat connexin43 (59% identity) and Xenopus connexin38 (66% identity) when compared from the NH2 terminus to the end of the fourth putative transmembrane region. When expressed in Xenopus oocytes Cx37 forms functional intercellular channels that exhibit more sensitive and rapid gating in response to voltage than any previously characterized vertebrate gap junction. Under stringent conditions the Cx37 cDNA hybridizes to an mRNA of 1.7 kb that is found highly abundant in lung and to progressively lesser extents in brain, kidney, skin, spleen, liver, intestine, and heart. Embryonic brain, kidney, and skin express two to fivefold higher levels of the Cx37 transcript than the corresponding adult tissues. Cx37 transcripts were also found to increase two to threefold in response to retinoic acid treatment of cultured embryonic carcinoma F9 cells.

Six genes of the human connexin gene family coding for gap junctional proteins are assigned to four different human chromosomes.

Connexin genes code for proteins that form cell-to-cell channels known as gap junctions. The genes for the known connexins 26, 32, 43, and 46 have been assigned to human chromosomes, 13, X, 6, and 13, respectively, by analysis of a panel of human-mouse somatic cell hybrids using rat cDNA probes. A pseudogene of connexin 43 that lacks an intron of the cx43 gene has been located on human chromosome 5. Furthermore, the genes of the two new connexins 37 and 40 have both been assigned to human chromosome 1. Thus the human chromosomes 1 and 13 each carry at least two different connexin genes. Their exact location on these chromosomes is not yet known. From our results subchromosomal assignments can be deduced for the human cx32 gene to Xq13-p11, the human cx37 gene as well as the human cx40 gene to 1pter-q12, and the human cx43 gene to 6q14-qter. The generation of the connexin multigene family from a hypothetical ancestral connexin gene is discussed.

Identification of a rat liver cDNA and mRNA coding for the 28 kDa gap junction protein.

By screening of a rat liver cDNA library with complex and deoxyinosine containing oligonucleotide probes a cDNA clone was isolated and shown by sequencing to code for the amino-terminal half of the rat liver 28 kDa gap junction protein. The insert hybridized to a 1.9 kb species from rat and mouse liver poly(A)+ RNA in Northern blot analysis. In embryonic mouse hepatocytes the amount of the 1.9 kb mRNA increased 3-fold between 24 and 96 h in culture. This correlates with the previously described increase of the 28 kDa gap junction protein under these conditions.