Beth A. Montelone

Cloning and Analysis of a Cryptosporidium parvum Gene Encoding a Protein with Homology to Cytoplasmic Form Hsp70

ABSTRACT. An intronless gene encoding a protein of 674 amino acid residues with a molecular mass of 73,403 Da showing homology to the cytoplasmic form of the 70 kDa heat shock proteins has been cloned and sequenced from the intestinal pathogen Cryptosporidium parvum. Monospecific polyclonal antibodies obtained to recombinant protein recognized a single band with an approximate molecular mass of 70 kDa on a Western blot of C. parvum proteins, as well as the 70 kDa heat shock protein from bovine brain. Southern blot analysis suggested the gene was single copy in the C. parvum genome. Eleven perfect repeats of the sequence GGMP were found in the predicted protein near the carboxyl terminus.

Irreversible UV Inactivation of Cryptosporidium spp. Despite the Presence of UV Repair Genes1

Abstract Ultraviolet light is being considered as a disinfectant by the water industry because it appears to be very effective for inactivating pathogens, including Cryptosporidium parvum. However, many organisms have mechanisms for repairing ultraviolet light-induced DNA damage, which may limit the utility of this disinfection technology. Inactivation of C. parvum was assessed by measuring infectivity in cells of the human ileocecal adenocarcinoma HCT-8 cell line, with an assay targeting a heat shock protein gene and using a reverse transcriptase polymerase chain reaction to detect infections. Oocysts of five different isolates displayed similar sensitivity to ultraviolet light. An average dosage of 7.6 mJ/cm2 resulted in 99.9% inactivation, providing the first evidence that multiple isolates of C. parvum are equally sensitive to ultraviolet disinfection. Irradiated oocysts were unable to regain pre-irradiation levels of infectivity, following exposure to a broad array of potential repair conditions, such as prolonged incubation, pre-infection excystation triggers, and post-ultraviolet holding periods. A combination of data-mining and sequencing was used to identify genes for all of the major components of a nucleotide excision repair complex in C. parvum and Cryptosporidium hominis. The average similarity between the two organisms for the various genes was 96.4% (range, 92–98%). Thus, while Cryptosporidum spp. may have the potential to repair ultraviolet light-induced damage, oocyst reactivation will not occur under the standard conditions used for storage and distribution of treated drinking water.

Improving baculovirus resistance to UV inactivation: increased virulence resulting from expression of a DNA repair enzyme

The use of baculoviruses as biological control agents is hampered by their susceptibility to inactivation by ultraviolet (UV) light. In an attempt to reduce UV inactivation, an algal virus pyrimidine dimer-specific glycosylase, cv-PDG, was expressed in the baculovirus Autographa californica M nucleopolyhedrovirus (AcMNPV), and the infectivity of recombinant viruses expressing cv-PDG was measured after exposure to UV light. Expression of cv-PDG resulted in a 3-fold decrease in inactivation of budded virus by UV as measured by plaque assay in Spodoptera frugiperda Sf21 cells. However, occluded viruses expressing cv-PDG were not more resistant to UV inactivation than wild type AcMNPV when fed to either S. frugiperda or Trichoplusia ni neonate larvae. Surprisingly, however, viruses expressing cv-PDG showed a significant decrease in both the dose of occluded virus required for oral lethality and the time required for lethality compared to control virus, but these effects were only seen in S. frugiperda and not in T. ni larvae.

The putative acetyl-coa synthetase gene of Cryptosporidium parvum and a new conserved protein motif in acetyl-coa synthetases

We determined the nucleotide (nt) sequence of the putative gene encoding acetyl-coenzyme A synthetase (ACS) from the parasitic protozoan Cryptosporidium parvum. The gene is single copy, located on a chromosome of approximately 1.08 mb, and has no introns. The gene is characterized by low codon usage bias and encodes a 694-amino acid (aa) protein with a predicted molecular size of 78 kDa, similar to other ACSs from different prokaryotic and eukaryotic species. Comparison of multiple protein alignments of ACSs revealed a new conserved sequence motif PKT(R/V/L)SGK(I/V/T)(T/M/V/K)R(R/N) near the C-terminus, which may be a signature for ACSs. This motif shares significant homology with sequences from other members of the AMP-binding family, has secondary structure similar to the purine-binding motif of ATP- and GTP-ases, and may play a role in the enzymatic activity of proteins from the AMP-binding family.

Sequence of the parasitic protozoan, Cryptosporidium parvum, putative protein disulfide isomerase-encoding DNA

A composite 1876-bp DNA encoding a putative protein disulfide isomerase (PDI) has been constructed from clones isolated from Cryptosporidium parvum (C. parvum) genomic and cDNA libraries and the nucleotide sequence determined. As predicted from the open reading frame (ORF), the protein product has a predicted molecular size of 54 kDa and a high degree of homology to PDIs from other species.

Interactions among mutations affecting spontaneous mutation, mitotic recombination, and DNA repair in yeast

The mutant alleles mms9-1, mms13-1, or mms21-1 of Saccharomyces cerevisiae confer pleiotropic effects, including sensitivity to the alkylating agent methyl methanesulfonate, elevations in spontaneous mutation and mitotic recombination, defects in meiosis, and cross-sensitivity to radiation. We constructed double-mutant strains containing an mms mutation and a defect in either excision repair, mutagenic repair, or recombinational repair and measured the levels of spontaneous mutation and mitotic reombination. Double mutants lacking excision repair show elevations in spontaneous mutation but with predominantly unchanged levels of mitotic recombination. RAD52 function was required for the expression of the hyper-recombination phenotype of the mms9-1, mms13-1, and mms21-1 alleles; double mutants displayed the very low recombination levels characteristic of rad52 mutants. Phenotypes of double mutants containing one of the mms alleles and either of the hyper-recombination/mutator rad6-1 or rad3-102 alleles suggest that the mutagenic lesions in mms strains may not be identical to the recombinogenic lesions.

Assessment of the Effectiveness of the Studio Format in Introductory Undergraduate Biology

Kansas State University converted its introductory biology course, previously taught as an audio-tutorial (A-T), to a studio format in 1997. We share with others information about the process involved and present assessment data for the studio format course that address 1) student exam performance in A-T and studio; 2) student course grades in A-T and studio; 3) student and instructor perceptions and attitudes for A-T and studio; 4) student performance in subsequent biology courses for A-T and studio; and 5) gains in student learning for the studio course and other traditional lecture/lab courses. Collectively, these measures demonstrate that the studio format is as effective as or more effective (for some measures) than the A-T approach and traditional approaches in providing an effective learning environment. We discuss the issues involved in comparing course formats.

Interaction of excision repair gene products and mitotic recombination functions in yeast

We have tested the ability of mutants of three additional genes in the excision repair pathway of Saccharomyces cerevisiae to suppress the hyper-recombination and rad52 double-mutant lethality phenotypes of the rad3-102 (formerly rem1-2) mutation. Such suppression has previously been been observed with mutant alleles of RAD1 and RAD4. We had hypothesized that the rad3-102 mutation created elevated levels of DNA lesions which could be processed by the products of the RAD1 and RAD4 genes into recombinogenic double-strand breaks requiring the RAD52 product for repair. In this report, we show that the RAD2, RAD7, and RAD10 genes are also necessary for this processing. We discuss our observations of varying levels of mitotic crossingover in Rem-rad double-mutant strains.

Sequence of the gene encoding hsp90e from Cryptosporidium parvum

A composite 2364 nt DNA sequence with an open reading frame (ORF) encoding an endoplasmic reticulum-associated heat shock protein 90 (CpHsp90e) was determined from clones isolated from genomic libraries constructed from the KSU-1 isolate of Cryptosporidium parvum. Transcription was verified by isolation of a clone from a cDNA library with a similar restriction map to that observed with genomic DNA. The predicted protein consists of 787 amino acids, has a predicted molecular size of 89.2 kDa, and was found to share strong homology with other endoplasmic reticulum-associated hsp90 proteins.

The rem mutations in the ATP-binding groove of the Rad3/XPD helicase lead to Xeroderma pigmentosum-Cockayne Syndrome-like phenotypes

The eukaryotic TFIIH complex is involved in Nucleotide Excision Repair and transcription initiation. We analyzed three yeast mutations of the Rad3/XPD helicase of TFIIH known as rem (recombination and mutation phenotypes). We found that, in these mutants, incomplete NER reactions lead to replication fork breaking and the subsequent engagement of the homologous recombination machinery to restore them. Nevertheless, the penetrance varies among mutants, giving rise to a phenotype gradient. Interestingly, the mutations analyzed reside at the ATP-binding groove of Rad3 and in vivo experiments reveal a gain of DNA affinity upon damage of the mutant Rad3 proteins. Since mutations at the ATP-binding groove of XPD in humans are present in the Xeroderma pigmentosum-Cockayne Syndrome (XP-CS), we recreated rem mutations in human cells, and found that these are XP-CS-like. We propose that the balance between the loss of helicase activity and the gain of DNA affinity controls the capacity of TFIIH to open DNA during NER, and its persistence at both DNA lesions and promoters. This conditions NER efficiency and transcription resumption after damage, which in human cells would explain the XP-CS phenotype, opening new perspectives to understand the molecular basis of the role of XPD in human disease.