Iain L. Johnstone

Cloning an Aspergillus nidulans developmental gene by transformation.

We have developed a transformation system for Aspergillus nidulans giving a frequency of transformation high enough to screen a gene bank from which we were able to isolate and clone the A. nidulans developmental gene brlA by visual selection. The vector contains the selective marker argB+, and with it a frequency of transformation of 500 stable transformants/micrograms plasmid DNA can regularly be achieved. The evidence suggests that transformation is by integration but spontaneous excision of integrated plasmids is apparently frequent enough to allow the recovery of transforming plasmids in Escherichia coli.

Isolation and characterisation of the crnA-niiA-niaD gene cluster for nitrate assimilation in Aspergillus nidulans

Genomic clones containing the entire crnA-niiA-niaD gene cluster of Aspergillus nidulans have been isolated, and the structures of the niiA and niaD genes have been determined by nucleotide sequence analysis. This gene cluster is required for the assimilation of nitrate in A. nidulans, and the three genes encode a product required for nitrate uptake and the enzymes, nitrite reductase and nitrate reductase, respectively. The putative coding sequences, as deduced by comparison to cDNA clones of both niiA and niaD, are interrupted by multiple small introns, and the two genes are divergently transcribed. Identification and characterization of specific mRNAs involved in nitrate assimilation indicates that only monocistronic transcripts are involved, and that the approximate sizes of these transcripts are 1.6 kb, 3.4 kb and 2.8 kb for crnA, niiA and niaD, respectively. The results also indicate that control of niiA and niaD gene expression is mediated by the levels of mRNA accumulation, in response to the source of nitrogen in the growth medium. Two types of transcripts for niiA were observed.

An autonomously replicating plasmid transforms Aspergillus nidulans at high frequency

From an unstable Aspergillus nidulans colony, resulting from transformation with an A. nidulans gene bank, a plasmid was reisolated which transformed A. nidulans at a frequency of 20,000 transformants per 10(6) protoplasts at near saturation levels of transforming DNA. This represents a 250-fold enhancement of transformation efficiency over that found for typical integrative vectors such as pILJ16, the plasmid used in gene bank constructions. The plasmid, designated ARp1, is 11.5 kb in size, and consists of sequences derived from the 5.4-kb gene bank vector pILJ16, which carries the A. nidulans gene argB, and a 6.1-kb insert, designated AMA1. Southern analysis of transformant DNA showed ARp1 to be maintained in free form and not integrated into the chromosome. It has a mean copy number of 10-30 per haploid genome, and is mitotically unstable, being lost from 65% of asexual progeny of transformants. It shows similar transformational properties in A. niger and A. oryzae.

cis regulatory requirements for hypodermal cell-specific expression of the Caenorhabditis elegans cuticle collagen gene dpy-7

The Caenorhabditis elegans cuticle collagens are encoded by a multigene family of between 50 and 100 members and are the major component of the nematode cuticular exoskeleton. They are synthesized in the hypodermis prior to secretion and incorporation into the cuticle and exhibit complex patterns of spatial and temporal expression. We have investigated the cis regulatory requirements for tissue- and stage-specific expression of the cuticle collagen gene dpy-7 and have identified a compact regulatory element which is sufficient to specify hypodermal cell reporter gene expression. This element appears to be a true tissue-specific promoter element, since it encompasses the dpy-7 transcription initiation sites and functions in an orientation-dependent manner. We have also shown, by interspecies transformation experiments, that the dpy-7 cis regulatory elements are functionally conserved between C. elegans and C. briggsae, and comparative sequence analysis supports the importance of the regulatory sequence that we have identified by reporter gene analysis. All of our data suggest that the spatial expression of the dpy-7 cuticle collagen gene is established essentially by a small tissue-specific promoter element and does not require upstream activator or repressor elements. In addition, we have found the DPY-7 polypeptide is very highly conserved between the two species and that the C. briggsae polypeptide can function appropriately within the C. elegans cuticle. This finding suggests a remarkably high level of conservation of individual cuticle components, and their interactions, between these two nematode species.

Functional characterization of SR and SR-related genes in Caenorhabditis elegans

The SR proteins constitute a family of nuclear phosphoproteins, which are required for constitutive splicing and also influence alternative splicing regulation. Initially, it was suggested that SR proteins were functionally redundant in constitutive splicing. However, differences have been observed in alternative splicing regulation, suggesting unique functions for individual SR proteins. Homology searches of the Caenorhabditis elegans genome identified seven genes encoding putative orthologues of the human factors SF2/ASF, SRp20, SC35, SRp40, SRp75 and p54, and also several SR‐related genes. To address the issue of functional redundancy, we used dsRNA interference (RNAi) to inhibit specific SR protein function during C.elegans development. RNAi with CeSF2/ASF caused late embryonic lethality, suggesting that this gene has an essential function during C.elegans development. RNAi with other SR genes resulted in no obvious phenotype, which is indicative of gene redundancy. Simultaneous interference of two or more SR proteins in certain combinations caused lethality or other developmental defects. RNAi with CeSRPK, an SR protein kinase, resulted in early embryonic lethality, suggesting an essential role for SR protein phosphorylation during development.

Cuticle collagen genes: expression in Caenorhabditis elegans

Collagen is a structural protein used in the generation of a wide variety of animal extracellular matrices. The exoskeleton of the free-living nematode, Caenorhabditis elegans, is a complex collagen matrix that is tractable to genetic research. Mutations in individual cuticle collagen genes can cause exoskeletal defects that alter the shape of the animal. The complete sequence of the C. elegans genome indicates upwards of 150 distinct collagen genes that probably contribute to this structure. During the synthesis of this matrix, individual collagen genes are expressed in distinct temporal periods, which might facilitate the formation of specific interactions between distinct collagens.

Temporal reiteration of a precise gene expression pattern during nematode development.

The nematode Caenorhabditis elegans is contained within a multifunctional exoskeleton, the cuticle, that contains a large number of distinct collagens. As the nematode proceeds from the egg through four larval stages to the adult, transition between larval stages is marked by synthesis of a new cuticle and subsequent moulting of the old one. This is a cyclically repeated developmental event, frequently described as the moulting cycle. We have examined the temporal expression of a group of six genes encoding distinct cuticular collagens. As expected, mRNA abundance for each of the six genes tested is found to oscillate, peaking once during each larval stage. Unexpectedly, the periods of abundance for each gene do not coincide, different genes being expressed at different times relative to one another within the moulting cycle. We detect a programme of temporally distinct waves of collagen gene expression, the precise pattern of which is repeated during each of the four larval stages. This multiphasic pattern of oscillating cuticular collagen gene expression indicates an unexpected complexity of temporal control during the nematode moulting cycle and has implications for collagen trimerization and cuticle synthesis.

Combined Extracellular Matrix Cross-linking Activity of the Peroxidase MLT-7 and the Dual Oxidase BLI-3 Is Critical for Post-embryonic Viability in Caenorhabditis elegans

The nematode cuticle is a protective collagenous extracellular matrix that is modified, cross-linked, and processed by a number of key enzymes. This Ecdysozoan-specific structure is synthesized repeatedly and allows growth and development in a linked degradative and biosynthetic process known as molting. A targeted RNA interference screen using a cuticle collagen marker has been employed to identify components of the cuticle biosynthetic pathway. We have characterized an essential peroxidase, MoLT-7 (MLT-7), that is responsible for proper cuticle molting and re-synthesis. MLT-7 is an active, inhibitable peroxidase that is expressed in the cuticle-synthesizing hypodermis coincident with each larval molt. mlt-7 mutants show a range of body morphology defects, most notably molt, dumpy, and early larval stage arrest phenotypes that can all be complemented with a wild type copy of mlt-7. The cuticles of these mutants lacks di-tyrosine cross-links, becomes permeable to dye and accessible to tyrosine iodination, and have aberrant collagen protein expression patterns. Overexpression of MLT-7 causes mutant phenotypes further supporting its proposed enzymatic role. In combination with BLI-3, an H2O2-generating NADPH dual oxidase, MLT-7 is essential for post-embryonic development. Disruption of mlt-7, and particularly bli-3, via RNA interference also causes dramatic changes to the in vivo cross-linking patterns of the cuticle collagens DPY-13 and COL-12. This points toward a functionally cooperative relationship for these two hypodermally expressed proteins that is essential for collagen cross-linking and proper extracellular matrix formation.

Caenorhabditis elegans exoskeleton collagen COL‐19: An adult‐specific marker for collagen modification and assembly, and the analysis of organismal morphology

The integral role that collagens play in the morphogenesis of the nematode exoskeleton or cuticle makes them a useful marker in the examination of the collagen synthesizing machinery. In this study, a green fluorescent protein–collagen fusion has been constructed by using the Caenorhabditis elegans adult‐specific, hypodermally synthesized collagen COL‐19. In wild‐type nematodes, this collagen marker localized to the circumferential annular rings and the lateral trilaminar alae of the cuticle. Crosses carried out between a COL‐19::GFP integrated strain and several morphologically mutant strains, including blister, dumpy, long, small, squat, and roller revealed significant COL‐19 disruption that was predominantly strain‐specific and provided a structural basis for the associated phenotypes. Disruption was most notable in the cuticle overlying the lateral seam cell syncytium, and confirmed the presence of two distinct forms of hypodermis, namely the circumferentially contracting lateral seam cells and the laterally contracting ventral–dorsal hypodermis. The effect of a single aberrant collagen being sufficient to mediate widespread collagen disruption was exemplified by the collagen mutant strain dpy‐5 and its disrupted COL‐19::GFP and DPY‐7 collagen expression patterns. Through the disrupted pattern of COL‐19 and DPY‐7 in a thioredoxin mutant, dpy‐11, and through RNA interference of a dual oxidase enzyme and a vesicular transport protein, we also show the efficacy of the COL‐19::GFP strain as a marker for aberrant cuticle collagen synthesis and, thus, for the identification of factors involved in the construction of collagenous extracellular matrices. Developmental Dynamics 226:000–000, 2003.

Molecular analysis of mutations in the Caenorhabditis elegans collagen gene dpy-7.

Collagens are a family of proteins contributing to the body structure of eukaryotes. They are encoded by a large and diverse gene family in the nematode Caenorhabditis elegans but by only a few genes in vertebrates. We have studied mutant alleles of the C. elegans dpy‐7 gene, one of a large group of genes whose mutant phenotype is altered body form and several of which have previously been shown to encode cuticular collagens. We made use of the C. elegans physical map to screen specifically for collagen genes in the region of the X chromosome to which dpy‐7 maps. This yielded a wild‐type collagen gene clone which we showed, by micro‐injection, could repair the dpy‐7 mutant phenotype in transgenic animals. We cloned the homologous sequence from four dpy‐7 mutant strains and by sequence analysis identified a single mutation in each case. All four mutations result in the substitution of a glycine with a larger residue in the conserved Gly‐X‐Y collagen domains. Similar substitutions in vertebrate collagens cause the heritable brittle bone disorder osteogenesis imperfecta. Whereas the human mutations are dominant, the dpy‐7 mutations are recessive, and this may reflect different levels of complexity of collagenous macromolecular structures in the two organisms.