Heterogeneous expression and functional analysis of two distinct replication protein A large subunits from Cryptosporidium parvum

Functions of alternative replication protein A in initiation and elongation

Replication protein A (RPA) is a single-stranded DNA-binding complex that is essential for DNA replication, repair, and recombination in eukaryotic cells. In addition to this canonical complex, we have recently characterized an alternative replication protein A complex (aRPA) that is unique to primates. aRPA is composed of three subunits: RPA1 and RPA3, also present in canonical RPA, and a primate-specific subunit RPA4, homologous to canonical RPA2. aRPA has biochemical properties similar to those of the canonical RPA complex but does not support DNA replication. We describe studies that aimed to identify what properties of aRPA prevent it from functioning in DNA replication. We show aRPA has weakened interaction with DNA polymerase alpha (pol alpha) and that aRPA is not able to efficiently stimulate DNA synthesis by pol alpha on aRPA-coated DNA. Additionally, we show that aRPA is unable to support de novo priming by pol alpha. Because pol alpha activity is essential for both initiation and Okazaki strand synthesis, we conclude that the inability of aRPA to support pol alpha loading causes aRPA to be defective in DNA replication. We also show that aRPA stimulates synthesis by DNA polymerase alpha in the presence of PCNA and RFC. This indicates that aRPA can support extension of DNA strands by DNA polymerase partial differential. This finding along with the previous observation that aRPA supports early steps of nucleotide excision repair and recombination indicates that aRPA can support DNA repair synthesis that requires polymerase delta, PCNA, and RFC and support a role for aRPA in DNA repair.

A naturally occurring human RPA subunit homolog does not support DNA replication or cell-cycle progression

Replication Protein A (RPA) is a single-stranded DNA-binding protein essential for DNA replication, repair, recombination and cell-cycle regulation. A human homolog of the RPA2 subunit, called RPA4, was previously identified and shown to be expressed in colon mucosal and placental cells; however, the function of RPA4 was not determined. To examine the function of RPA4 in human cells, we carried out knockdown and replacement studies to determine whether RPA4 can substitute for RPA2 in the cell. Unlike RPA2, exogenous RPA4 expression did not support chromosomal DNA replication and lead to cell-cycle arrest in G2/M. In addition, RPA4 localized to sites of DNA repair and reduced γ-H2AX caused by RPA2 depletion. These studies suggest that RPA4 cannot support cell proliferation but can support processes that maintain the genomic integrity of the cell.

Cryptosporidium: genomic and biochemical features

Recent progress in understanding the unique biochemistry of the two closely related human enteric pathogens Cryptosporidium parvum and Cryptosporidium hominis has been stimulated by the elucidation of the complete genome sequences for both pathogens. Much of the work that has occurred since that time has been focused on understanding the metabolic pathways encoded by the genome in hopes of providing increased understanding of the parasite biology, and in the identification of novel targets for pharmacological interventions. However, despite identifying the genes encoding enzymes that participate in many of the major metabolic pathways, only a hand full of proteins have actually been the subjects of detailed scrutiny. Thus, much of the biochemistry of these parasites remains a true mystery.

Differential expression of the two distinct replication protein A subunits from Cryptosporidium parvum

Apicomplexan parasites differ from their host by possessing at least two distinct types (long and short) of replication protein A large subunits (RPA1). Different roles for the long and short types of RPA1 proteins have been implied in early biochemical studies, but certain details remained to be elucidated. In the present study, we have found that the Cryptosporidium parvum short-type RPA1 (CpRPA1A) was highly expressed at S-phase in parasites during the early stage of merogony (a cell multiplication process unique to this group of parasites), but otherwise present in the cytosol at a much lower level in other cell-cycle stages. This observation indicates that CpRPA1A is probably responsible for the general DNA replication of the parasite. On the other hand, the long-type CpRPA1B protein was present in a much lower level in the early life cycle stages, but elevated at later stages involved in sexual development, indicating that CpRPA1B may play a role in DNA recombination. Additionally, CpRPA1B could be up-regulated by UV exposure, indicating that this long-type RPA1 is probably involved in DNA repair. Collectively, our data implies that the two RPA1 proteins in C. parvum are performing different roles during DNA replication, repair and recombination in this parasite.

The protozoan parasite Cryptosporidium parvum possesses two functionally and evolutionarily divergent replication protein A large subunits

Very little is known about protozoan replication protein A (RPA), a heterotrimeric complex critical for DNA replication and repair. We have discovered that in medically and economically important apicomplexan parasites, two unique RPA complexes may exist based on two different types of large subunit RPA1. In this study, we characterized the single-stranded DNA binding features of two distinct types (i.e. short and long) of RPA1 subunits from Cryptosporidium parvum (CpRPA1A and CpRPA1B). These two proteins differ from human RPA1 in their intrinsic single-stranded DNA binding affinity (K) and have significantly lower cooperativity (omega). We also identified the RPA2 and RPA3 subunits from C. parvum, the latter of which had yet to be reported to exist in any protozoan. Using fluorescence resonance energy transfer technology and pull-down assays, we confirmed that these two subunits interact with each other and with CpRPA1A and CpRPA1B. This suggests that the heterotrimeric structure of RPA complexes may be universally conserved from lower to higher eukaryotes. Bioinformatic analyses indicate that multiple types of RPA1 are present in the other apicomplexans Plasmodium and Toxoplasma. Apicomplexan RPA1 proteins are phylogenetically more related to plant homologues and probably arose from a single gene duplication event prior to the expansion of the apicomplexan lineage. Differential expression during the life cycle stages in three apicomplexan parasites suggests that the two RPA1 types exercise specialized biological functions.

Functional characterization of replication protein A2 (RPA2) from Cryptosporidium parvum

Replication protein A (RPA) is a heterotrimeric complex of single-stranded DNA-binding proteins that play multiple roles in eukaryotic DNA metabolism. The RPA complex is typically composed of heterologous proteins (termed RPA1, RPA2 and RPA3) in animals, plants and fungi, which possess different functions. Previously, two distinct, short-type RPA large subunits (CpRPA1 and CpRPA1B) from the apicomplexan parasite Cryptosporidium parvum were characterized. Here are reported the identification and characterization of a putative middle RPA subunit (CpRPA2) from this unicellular organism. Although the CpRPA2 gene encodes a predicted 40.1 kDa peptide, which is larger than other RPA2 subunits characterized to date, Western blot analysis of oocyst preparations detected a native CpRPA2 protein with a molecular mass of approximately 32 kDa, suggesting that CpRPA2 might undergo post-translational cleavage or the gene was translated at an alternative start codon. Immunofluorescence microscopy using a rabbit anti-CpRPA2 antibody revealed that CpRPA2 protein was mainly distributed in the cytosol (rather than the nuclei) of C. parvum sporozoites. Semi-quantitative RT-PCR data indicated that CpRPA2 was differentially expressed in a tissue culture model with highest expression in intracellular parasites infecting HCT-8 cells for 36 and 60 h. Sequence comparison suggests that RPA2 is a group of poorly conserved proteins. Nonetheless, functional analyses of recombinant proteins confirmed that CpRPA2 is a single-stranded DNA-binding protein and that it could serve as an in vitro phosphorylation target by a DNA-dependent protein kinase. The minimal length of poly(dT) required for CpRPA2 binding is 17 nucleotides, and the DNA-binding capability was inhibited by phosphorylation in vitro. These observations provide additional evidence on the divergence of RPA proteins between C. parvum and host, implying that the parasite DNA replication machinery could be explored as a chemotherapeutic target.

Differential expression and interaction of transcription co-activator MBF1 with TATA-binding protein (TBP) in the apicomplexan Cryptosporidium parvum

All gene-specific transcriptional activators initiate gene transcriptions by binding to promoter sequences and recruiting general transcription factors including TATA-binding protein (TBP) to upstream of targeted genes. Some of them require multiprotein bridging factors (MBFs); for example, the type 1 MBF (MBF1) which interconnects the gene activator with TBP. In this study, the properties of a previously cloned type 1 multiprotein bridging factor (CpMBF1) and a newly identified TBP (CpTBP1) from the apicomplexan Cryptosporidium parvum were investigated. Genes encoding both proteins were differentially expressed as determined by semi-quantitative RT-PCRs during the parasite life cycle, but in different patterns. The highest level of expression of CpMBF1 was in the well-developed intracellular parasites, whereas that of CpTBP1 was found in intact oocysts and late intracellular stages, possibly correlated with the formation of oocysts. Both CpMBF1 and CpTBP1 were expressed as maltose-binding protein fusion proteins. The function of CpTBP1 was confirmed by its ability to bind a biotinylated DNA oligonucleotide containing TATA consensus sequence. The interaction between CpMBF1 and CpTBP1 was also observed by an electrophoretic mobility shift assay. Since little is known about the regulation and control of gene activity in C. parvum, this study may point to a new direction for the study of gene activation associated with the development of the complex life cycle of this parasite.