Calcitonin gene-related peptide: key regulator of cutaneous immunity.

Calcitonin gene-related peptide (CGRP) has been viewed as a neuropeptide and vasodilator. However, CGRP is more appropriately thought of as a pleiotropic signalling molecule. Indeed, CGRP has key regulatory functions on immune and inflammatory processes within the skin. CGRP-containing nerves are intimately associated with epidermal Langerhans cells (LCs), and CGRP has profound regulatory effects on Langerhans cell antigen-presenting capability. When LCs are exposed to CGRP in vitro, their ability to present antigen for in vivo priming of naïve mice or elicitation of delayed-type hypersensitivity is inhibited in at least some situations. Administration of CGRP intradermally inhibits acquisition of immunity to Th1-dominant haptens applied to the injected site while augmenting immunity to Th2-dominant haptens, although the cellular targets of activity in these experiments remain unclear. Although CGRP can be a pro-inflammatory agent, several studies have demonstrated that administration of CGRP can inhibit the elicitation of inflammation by inflammatory stimuli in vivo. In this regard, CGRP inhibits the release of certain chemokines by stimulated endothelial cells. This is likely to be physiologically relevant as cutaneous blood vessels are innervated by sensory nerves. Exciting new studies suggest a significant role for CGRP in the pathogenesis of psoriasis and, most strikingly, that CGRP inhibits the ability of LCs to transmit the human immunodeficiency virus 1 to T lymphocytes. A more complete understanding of the role of CGRP in the skin immune system may lead to new and novel approaches for the therapy of immune-mediated skin disorders.

Saccharomyces cerevisiae contains an RNase MRP that cleaves at a conserved mitochondrial RNA sequence implicated in replication priming.

Yeast mitochondrial DNA contains multiple promoters that sponsor different levels of transcription. Several promoters are individually located immediately adjacent to presumed origins of replication and have been suggested to play a role in priming of DNA replication. Although yeast mitochondrial DNA replication origins have not been extensively characterized at the primary sequence level, a common feature of these putative origins is the occurrence of a short guanosine-rich region in the priming strand downstream of the transcriptional start site. This situation is reminiscent of vertebrate mitochondrial DNA origins and raises the possibility of common features of origin function. In the case of human and mouse cells, there exists an RNA processing activity with the capacity to cleave at a guanosine-rich mitochondrial RNA sequence at an origin; we therefore sought the existence of a yeast endoribonuclease that had such a specificity. Whole cell and mitochondrial extracts of Saccharomyces cerevisiae contain an RNase that cleaves yeast mitochondrial RNA in a site-specific manner similar to that of the human and mouse RNA processing activity RNase MRP. The exact location of cleavage within yeast mitochondrial RNA corresponds to a mapped site of transition from RNA to DNA synthesis. The yeast activity also cleaved mammalian mitochondrial RNA in a fashion similar to that of the mammalian RNase MRPs. The yeast endonuclease is a ribonucleoprotein, as judged by its sensitivity to nucleases and proteinase, and it was present in yeast strains lacking mitochondrial DNA, which demonstrated that all components required for in vitro cleavage are encoded by nuclear genes. We conclude that this RNase is the yeast RNase MRP.

Nucleotide sequence of the Varkud mitochondrial plasmid of Neurospora and synthesis of a hybrid transcript with a 5' leader derived from mitochondrial RNA.

The Mauriceville and Varkud mitochondrial plasmids of Neurospora are closely related, closed circular DNAs (3.6 and 3.7 kb, respectively; 1 kb = 10(3) bases or base-pairs), whose characteristics suggest relationships to mitochondrial DNA introns and retrotransposons. Here, we characterized the structure of the Varkud plasmid, determined its complete nucleotide sequence and mapped its major transcripts. The Mauriceville and Varkud plasmids have more than 97% positional identity. Both plasmids contain a 710 amino acid open reading frame that encodes a reverse transcriptase-like protein. The amino acid sequence of this open reading frame is strongly conserved between the two plasmids (701/710 amino acids) as expected for a functionally important protein. Both plasmids have a 0.4 kb region that contains five PstI palindromes and a direct repeat of approximately 160 base-pairs. Comparison of sequences in this region suggests that the Varkud plasmid has diverged less from a common ancestor than has the Mauriceville plasmid. Two major transcripts of the Varkud plasmid were detected by Northern hybridization experiments: a full-length linear RNA of 3.7 kb and an additional prominent transcript of 4.9 kb, 1.2 kb longer than monomer plasmid. Remarkably, we find that the 4.9 kb transcript is a hybrid RNA consisting of the full-length 3.7 kb Varkud plasmid transcript plus a 5' leader of 1.2 kb that is derived from the 5' end of the mitochondrial small rRNA. This and other findings suggest that the Varkud plasmid, like certain RNA viruses, has a mechanism for joining heterologous RNAs to the 5' end of its major transcript, and that, under some circumstances, nucleotide sequences in mitochondria may be recombined at the RNA level.

Yeast mitochondrial RNA polymerase is homologous to those encoded by bacteriophages T3 and T7.

Analysis of the nucleotide sequence of the genetic locus for yeast mitochondrial RNA polymerase (RPO41) reveals a continuous open reading frame with the coding potential for a polypeptide of 1351 amino acids, a size consistent with the electrophoretic mobility of this enzymatic activity. The transcription product from this gene spans the singular reading frame. In vivo transcript abundance reflects codon usage and growth under stringent conditions for mitochondrial biogenesis and function results in a several fold higher level of gene expression than growth under glucose repression. A comparison of the yeast mitochondrial RNA polymerase amino acid sequence to those of E. coli RNA polymerase subunits failed to demonstrate any regions of homology. Interestingly, the mitochondrial enzyme is highly homologous to the DNA-directed RNA polymerases of bacteriophages T3 and T7, especially in regions most highly conserved between the T3 and T7 enzymes themselves.

The DNA sequence and genetic organization of a Neurospora mitochondrial plasmid suggest a relationship to introns and mobile elements.

We have determined the complete 3581 bp sequence of the mitochondrial plasmid from Neurospora crassa strain Mauriceville-1c. The plasmid contains a long open reading frame that is expressed in its major transcript and could encode a hydrophilic protein of 710 amino acids. Two characteristics of the plasmid--codon usage and the presence of conserved sequence elements--suggest that it is related to Group I mtDNA introns. The major transcripts of the plasmid are approximately full-length, colinear RNAs that have heterogenous 5' ends and a single major 3' end. The major 5' and 3' ends are adjacent and slightly overlapping. The Mauriceville plasmid may belong to a class of genetic elements that were or are the progenitors of mtDNA introns.

Characterization of deletion derivatives of an autonomously replicating Neurospora plasmid.

We previously described two plasmids that replicate autonomously in both Neurospora and E. coli (Stohl and Lambowitz, Proc. Natl. Acad. Sci., U.S.A. 80, 1058-1062, 1983). One plasmid, pALS1, consists of the Neurospora ga-2+ gene (3 kb Hind III-fragment), the mitochondrial plasmid from N. intermedia strain P405-Labelle, and E. coli plasmid pBR325. The other, pALS2, is a putative deletion derivative of pALS1 that lacks most or all of the Labelle insert and that was repeatedly recovered from Neurospora transformants. We have now sequenced the region encompassing the deletion in five pALS2 plasmids isolated independently in two different laboratories. All five plasmids are identical in this region and completely lack the Labelle insert. We have also characterized an additional deletion derivative that retains a small (approximately 0.5 kb) segment of the Labelle insert. The results for pALS2 suggest that pBR325 plus the ga-2+ segment constitute a Neurospora replicon.

A colony filter-hybridization procedure for the filamentous fungus Neurospora crassa.

A colony filter-hybridization procedure for the filamentous fungus Neurospora crassa has been developed. The procedure is sensitive enough to detect Escherichia coli plasmid pBR322 DNA integrated into chromosomal DNA in a Neurospora transformant. Thus, it should facilitate the isolation of nuclear genes by plasmid-rescue procedures.

A family of repetitive palindromic sequences found in Neurospora mitochondrial DNA is also found in a mitochondrial plasmid DNA.

Neurospora mtDNA contains a repetitive, 18 nucleotide palindromic sequence (5'-CCCTGCAGTACTGCAGGG-3') that contains two closely spaced PstI sites (CTGCAG) in the arms of the palindrome (Yin, S., Heckman, J., and RajBhandary, U. L. (1981) Cell 26, 325-332). In the present study, DNA sequence analysis was carried out to determine whether PstI palindromes are present in an apparently distinct genetic element, the 3.6-kilobase mitochondrial plasmid from Neurospora crassa strain Mauriceville-1c (FGSC 2225). The plasmid contains a cluster of closely spaced PstI sites extending over a 0.4-kilobase region (Collins, R. A., Stohl, L. L., Cole, M. D., and Lambowitz, A. M. (1981) Cell 24, 443-452). The DNA sequence shows that the cluster consists of eight PstI sites organized in five palindromic elements. Two of the elements are identical with the canonical sequence found in mtDNA, whereas the remaining three elements differ from the canonical sequence by a few nucleotides. The occurrence of the PstI palindromes in two otherwise unrelated DNA species is consistent with the hypothesis that they are related to mobile DNA sequences that either propagate or were once capable of propagating within mitochondria.

Construction of a shuttle vector for the filamentous fungus Neurospora crassa.

We have constructed a recombinant plasmid, pALS-1, that replicates autonomously in both Neurospora and Escherichia coli. pALS-1 consists of the mitochondrial plasmid from Neurospora strain P405-Labelle, the Neurospora qa-2+ gene, and E. coli plasmid pBR325. pALS-1 transforms the Neurospora qa-2+ gene at frequencies 5- to 10-fold higher than those for plasmids that transform mainly by integration. When E. coli was transformed with DNA from Neurospora transformants, we recovered not only pALS-1 but also a smaller plasmid, pALS-2, which had undergone deletion of most and possibly all Labelle sequences, and the immediately flanking sequences in pBR325. pALS-2 also appears to replicate autonomously in Neurospora, but less efficiently than does pALS-1. Southern blots show that free pALS-1 and pALS-2 are present in nuclear and cytosolic (supernatant from high-speed centrifugation) fractions of Neurospora transformants and that small, variable proportions of the plasmids also can be detected in mitochondria. pALS-1 and pALS-2 constitute putative shuttle vectors for Neurospora.

Characterization of two new plasmid DNAs found in mitochondria of wild-type Neurospora intermedia strains.

Mitochondria from two Neurospora intermedia strains (P4O5-Labelle and Fiji N6-6) were found to contain plasmid DNAs in addition to the standard mitochondrial DNA species. The plasmid DNAs consist of monomeric circles (4.1-4.3 kbp and 5.2-5.3 kbp for Labelle and Fiji, respectively) and oligomers in which monomers are organized as head-to-tail repeats. DNA-DNA hybridization experiments showed that the plasmids have no substantial sequence homology to mtDNA, to each other, or to a previously characterized mitochondrial plasmid from N. crassa strain Mauriceville-lc (Collins et al. Cell 24, 443-452, 1981). The intramitochondrial location of the plasmids was established by cell fractionation and nuclease protection experiments. In sexual crosses, the plasmids showed strict maternal inheritance, the same as Neurospora mitochondrial DNA. The plasmids may represent a novel class of mitochondrial genetic elements.

Characterization of a novel plasmid DNA found in mitochondria of N. crassa.

We have identified a plasmid DNA that is found within mitochondria of wild-type N. crassa strain Mauriceville-1c (FGSC #2225), but that shows no detectable sequence homology with mitochondrial DNA. The plasmid DNA consists of an oligomeric series of circular molecules of monomer length 3.6 kb. There are two unusual clusters of restriction enzyme sites, one consisting of six Eco RI sites in a 1 kb region, and the other of five or more Pst I sites in a 0.4 kb region. RNA gel transfer hybridization experiments show a major transcript 3.3 to 3.4 kb long, close to the monomer length of the plasmid. The latter finding implies that the plasmid DNA contains specific sites for the initiation and termination of transcription.

Deletion mutants of Neurospora crassa mitochondrial DNA and their relationship to the "stop-start" growth phenotype.

"Stoppers" are a class of Neurospora crassa extranuclear mutants characterized by gross deficiencies of cytochromes b and aa3 and an unusual growth phenotype which involves irregular periods of growth andnongrowth. In the present work, mtDNAs from all four stopper mutants were found to contain deletions or insertions detectable by restriction enzyme analysis. [stp] mtDNA consists predominantly of defective molecules which retain a 16-megadalton segment (EcoRI-1, -4, and -6) of wild-type mtDNA (40 megadaltons). The other stopper mutants show smaller alterations: [stp A18t]-618, a 0.35-kilobase deletion in EcoRI-7b; [stp B2]-651, a 4-kilobase insertion in EcoRI-2; and [stp A]-574, a 5-kilobase deletion in EcoRI-2 and -10. Based on these results, we propose that "stop-start" growth results from competition between certain defective mtDNAs which have a tendency to predominate and low concentrations of less defective mtDNA species which must be retained to sustain growth. Three additional extranuclear mutants ("nonstoppers") have also been found to contain deletions in mtDNA. Remarkably, the defective mtDNA species in two of these mutants ([poky]H1-10 and [SG-3]-551) retain different sizes (18 and 13 megadlatons, respectively) of the same region retained in [stp] mtDNA (i.e., EcoRI-1, -4, and -6). The findings suggest that production of defective mtDNAs in Neurospora is nonrandom with a preferred mechanism leading to retention of this segment. It may be significant that the retained segment contains both mitochondrial rRNA genes and most mitochondrial tRNA genes. These deletion mutants may provide a tool for genetic mapping of Neurospora mtDNA.