A Salivary Gland Resident Macrophage Subset Regulating Radiation Responses.

Radiotherapy of head and neck cancers frequently leads to irreversible hypofunction of salivary glands, which severely compromises the quality of life and is extremely difficult to treat. We found recently that salivary gland resident macrophages are sensitive to radiation and interact with epithelial progenitors and endothelial cells through homeostatic paracrine factors. Heterogeneous subpopulations of resident macrophages are present in other organs with distinct functions, whereas subpopulations of salivary gland resident macrophages with distinct functions or transcriptional profiles have not been reported yet. Using single-cell RNA sequencing, we found that mouse submandibular glands (SMGs) contain 2 distinct self-renewing resident macrophage subsets, an MHC-IIhi subset present in many other organs and an uncommon Csf2r+ subset. The main source of Csf2 in SMGs are innate lymphoid cells (ILCs) that rely on IL15 for maintenance, while the main source of IL15 protein is Csf2r+ resident macrophages, indicating a homeostatic paracrine interaction between these cells. Csf2r+ resident macrophages are the major source of hepatocyte growth factor (Hgf) that regulates homeostasis of SMG epithelial progenitors. Meanwhile, Csf2r+ resident macrophages are responsive to Hedgehog signaling that can rescue salivary function impaired by radiation. Consistently, irradiation persistently decreased numbers of ILCs and levels of IL15 and Csf2 in SMGs, which were all recovered by transient activation of Hedgehog signaling after radiation. Csf2r+ resident macrophages and MHC-IIhi resident macrophages share transcriptome profiles of perivascular macrophages and macrophages associated with nerves and/or epithelial cells in other organs, respectively, and such niche preferences were supported by lineage tracing and immunofluorescent staining. These findings reveal an uncommon resident macrophage subset that regulates the homeostasis of the salivary gland and is promising as the target to restore salivary gland function impaired by radiation.

Transcriptome analysis of the binucleate ciliate Tetrahymena thermophila with asynchronous nuclear cell cycles.

Tetrahymena thermophila harbors two functionally and physically distinct nuclei within a shared cytoplasm. During vegetative growth, the "cell cycles" of the diploid micronucleus and polyploid macronucleus are offset. Micronuclear S phase initiates just before cytokinesis and is completed in daughter cells before onset of macronuclear DNA replication. Mitotic micronuclear division occurs mid-cell cycle, while macronuclear amitosis is coupled to cell division. Here we report the first RNA-seq cell cycle analysis of a binucleated ciliated protozoan. RNA was isolated across 1.5 vegetative cell cycles, starting with a macronuclear G1 population synchronized by centrifugal elutriation. Using MetaCycle, 3244 of the 26,000+ predicted genes were shown to be cell cycle regulated. Proteins present in both nuclei exhibit a single mRNA peak that always precedes their macronuclear function. Nucleus-limited genes, including nucleoporins and importins, are expressed before their respective nucleus-specific role. Cyclin D and A/B gene family members exhibit different expression patterns that suggest nucleus-restricted roles. Periodically expressed genes cluster into seven cyclic patterns. Four clusters have known PANTHER gene ontology terms associated with G1/S and G2/M phase. We propose that these clusters encode known and novel factors that coordinate micro- and macronuclear-specific events such as mitosis, amitosis, DNA replication, and cell division.

Deletion of the Tetrahymena thermophila rDNA replication fork barrier region disrupts macronuclear rDNA excision and creates a fragile site in the micronuclear genome.

During macronuclear development the Tetrahymena thermophila ribosomal RNA gene is excised from micronuclear chromosome 1 by site-specific cleavage at chromosome breakage sequence (Cbs) elements, rearranged into a 'palindromic' 21 kb minichromosome and extensively amplified. Gene amplification initiates from origins in the 5' non-transcribed spacer, and forks moving toward the center of the palindrome arrest at a developmentally regulated replication fork barrier (RFB). The RFB is inactive during vegetative cell divisions, suggesting a role in the formation or amplification of macronuclear rDNA. Using micronuclear (germline) transformation, we show that the RFB region facilitates Cbs-mediated excision. Deletion of the RFB inhibits chromosome breakage in a sub-population of developing macronuclei and promotes alternative processing by a Cbs-independent mechanism. Remarkably, the RFB region prevents spontaneous breakage of chromosome 1 in the diploid micronucleus. Strains heterozygous for DeltaRFB and wild-type rDNA lose the DeltaRFB allele and distal left arm of chromosome 1 during vegetative propagation. The wild-type chromosome is subsequently fragmented near the rDNA locus, and both homologs are progressively eroded, suggesting that broken micronuclear chromosomes are not 'healed' by telomerase. Deletion of this 363 bp segment effectively creates a fragile site in the micronuclear genome, providing the first evidence for a non-telomere cis-acting determinant that functions to maintain the structural integrity of a mitotic eukaryotic chromosome.

Cloning and biochemical analysis of the tetrahymena origin binding protein TIF1: competitive DNA binding in vitro and in vivo to critical rDNA replication determinants.

Cis-acting type I elements regulate the initiation of DNA replication, replication fork movement, and transcription of the Tetrahymena thermophila rDNA minichromosome and are required for cell cycle-controlled replication and developmentally programmed gene amplification. Previous studies identified three in vitro single-stranded type I element binding activities that were proposed to play distinct roles in replication control. Here we describe the cloning of one of these genes, TIF1, and we provide evidence for its association with type I elements in vivo. Furthermore, we show that TIF1 interacts (in vitro and in vivo) with pause site elements (PSE), which co-localize with replication initiation and fork arrest sites, and are shown to be essential. The in vivo accessibility of PSE and type I elements to potassium permanganate suggests that origin regions are frequently unwound in native chromatin. TIF1 contains sequence similarity to the Solanum tuberosum single strand-specific transcription factor, p24, and a related Arabidopsis protein. Antisense inhibition studies suggest that TIF1 competes with other proteins for PSE and type I element binding. TIF1 displays a marked strand bias in vivo, discriminating between origin- and promoter-proximal type I elements. We propose that this bias selectively modulates the binding of a different subset of proteins to the respective regulatory elements.

Allele-specific protein-DNA interactions between the single-stranded DNA-binding protein, ssA-TIBF, and DNA replication determinants in Tetrahymena.

Type I elements are multifunctional, cis-acting determinants that regulate the initiation of DNA replication, replication fork movement and transcription of the Tetrahymena thermophila rDNA minichromosome. Previous studies identified a protein, ssA-TIBF, that binds specifically to the A-rich strand of type I elements. Here, we examine interactions of ssA-TIBF with the wild-type C3 allele, and a natural variant, B rDNA, which manifests a defect in replication initiation and fork pausing. Purified ssA-TIBF is a homotetramer that binds one substrate molecule and contacts DNA via a single 24 kDa subunit. Both the A-rich and T-rich strands of type I elements are bound by ssA-TIBF, suggesting that this protein might stabilize replication origins in their unwound state. Nucleotides downstream of type I elements contribute to DNA binding, with the extent of DNA-protein contact being greater for wild-type C3 rDNA compared to B rDNA. Allele-specific protein-DNA contacts also occur within the conserved type I element itself. Despite these differences, the binding affinities of ssA-TIBF for C3 and B rDNA substrates are indistinguishable. Consequently, the mode of DNA binding must account for any role ssA-TIBF might play in the regulation of rDNA replication.

Three different proteins recognize a multifunctional determinant that controls replication initiation, fork arrest and transcription in Tetrahymena.

Type I elements regulate the initiation of DNA replication, elongation of replication forks and transcription of the Tetrahymena thermophila rDNA minichromosome. Previous studies identified a 24 kDa protein, ssA-TIBF, which binds the A-rich strand of type I elements. Here we describe two additional type I element binding activities (native mol. wt approximately 65 and approximately 250 kDa) that interact with DNA via previously unidentified 32 and 110 kDa polypeptides. The 65 kDa activity was purified to homogeneity and consists of a homodimer of a 32 kDa polypeptide. In contrast to the other type I element binding factors, the 65 kDa activity partitions preferentially to the nuclear fraction during isolation. Levels of the 65 kDa activity increase dramatically in starved cells, raising the possibility that it might negatively regulate replication or transcription. By comparison, the other two binding activities were elevated slightly during macronuclear development, when the rDNA was undergoing DNA replication. Previous studies indicate that the initiation of rDNA replication is regulated by long range interactions between dispersed type I elements. Competitive DNA binding or cooperative protein-protein interactions between the factors described here may play a regulatory role in replication or expression of the rDNA minichromosome.

Identification of an essential proximal sequence element in the promoter of the telomerase RNA gene of Tetrahymena thermophila.

Telomerase is a ribonucleoprotein reverse transcriptase that synthesizes and maintains telomeric DNA. Studies of telomeres and telomerase are facilitated by the large number of linear DNA molecules found in ciliated protozoa, such as Tetrahymena thermophila. To examine the expression of telomerase, we investigated the transcription of the RNA polymerase III-directed gene encoding the RNA subunit (TER1) of this enzyme. A chimeric gene containing the Glaucoma chattoni TER1 transcribed region flanked by 5' and 3' Tetrahymena regions was used to identify promoter elements following transformation of Tetrahymena cells. Disruption of a conserved proximal sequence element (PSE) located at -55 in the Tetrahymena TER1 5' flanking region eliminated expression of the chimeric gene. In addition, mutation of an A/T-rich element at -25 decreased expression markedly. A gel mobility shift assay and protein-DNA cross-linking identified a PSE-binding polypeptide of 50-60 kDa in Tetrahymena extracts. Gel filtration analysis revealed a native molecular mass of approximately 160 kDa for this binding activity. Our results point to a similar architecture between ciliate telomerase RNA and metazoan U6 small nuclear RNA promoters.

Long range cooperative interactions regulate the initiation of replication in the Tetrahymena thermophila rDNA minichromosome.

The Tetrahymena thermophila rDNA exists as a 21 kb palindromic minichromosome with two initiation sites for replication in each half palindrome. These sites localize to the imperfect, repeated 430 bp segments that include the nucleosome-free domains 1 and 2 (D1 and D2). To determine if the D1 and D2 segments act independently or in concert to control initiation, stable DNA transformation assays were performed. Single domain derivatives of the plasmid prD1 failed to support autonomous replication in Tetrahymena. Instead, such constructs propagated exclusively by integration into endogenous rDNA minichromosomes and displayed weak origin activity as detected by 2D gel electrophoresis. D1/D1 and D2/D2 derivatives also transformed Tetrahymena poorly, showing similar replication defects. Hence, the D1 and D2 segments are functionally non-redundant and cooperate rather than compete to control initiation. The observed replication defect was greatly reduced in a plasmid derivative that undergoes palindrome formation in Tetrahymena, suggesting that a compensatory mechanism overcomes this replication block. Finally, using a transient replication assay, we present evidence that phylogenetically-conserved type I elements directly regulate DNA replication. Taken together, our data support a model in which cooperative interactions between dispersed elements coordinately control the initiation of DNA replication.

Conserved cis- and trans-acting determinants for replication initiation and regulation of replication fork movement in tetrahymenid species.

The rDNA minichromosomes of Tetrahymena thermophila and Tetrahymena pyriformis share a high degree of sequence similarity and structural organization. The T.thermophila 5' non-transcribed spacer (5' NTS) is sufficient for replication and contains three repeated sequence elements that are conserved in T.pyriformis , including type I elements, the only known determinant for replication control. To assess the role of conserved sequences in replication control, structural and functional studies were performed on T.pyriformis rDNA. Similar to T.thermophila , replication initiates exclusively in the 5' NTS, localizing to a 900 bp segment. Elongating replication forks arrest transiently at one site which bears strong similarity to a tripartite sequence element present at fork arrest sites in T.thermophila rDNA. An in vitro type I element binding activity indistinguishable from the T.thermophila protein, ssA-TIBF, was detected in T.pyriformis extracts. The respective TIBF proteins bind with comparable affinity to type I elements from both species, suggesting that in vivo recognition could cross species boundaries. Despite these similarities, the T.pyriformis 5' NTS failed to support replication in transformed T.thermophila cells, suggesting a more complex genetic organization than previously realized.

Developmental regulation of DNA replication: replication fork barriers and programmed gene amplification in Tetrahymena thermophila.

The palindromic Tetrahymena ribosomal DNA (rDNA) minichromosome is amplified 10,000-fold during development. Subsequent vegetative replication is cell cycle regulated. rDNA replication differs fundamentally in cycling vegetative and nondividing amplifying cells. Using two-dimensional gel electrophoresis, we show for the first time that replication origins that direct gene amplification also function in normal dividing cells. Two classes of amplification intermediates were identified. The first class is indistinguishable from vegetative rDNA, initiating in just one of the two 5' nontranscribed spacer (NTS) copies in the rDNA palindrome at either of two closely spaced origins. Thus, these origins are active throughout the life cycle and their regulation changes at different developmental stages. The second, novel class of amplification intermediates is generated by multiple initiation events. Intermediates with mass greater than fully replicated DNA were observed, suggesting that onionskin replication occurs at this stage. Unlike amplified rDNA in Xenopus laevis, the novel Tetrahymena species are not produced by random initiation; replication also initiates in the 5' NTS. Surprisingly, a replication fork barrier which is activated only in these amplifying molecules blocks the progression of forks near the center of the palindrome. Whereas barriers have been previously described, this is the first instance in which programmed regulation of replication fork progression has been demonstrated in a eukaryote.

Type I elements mediate replication fork pausing at conserved upstream sites in the Tetrahymena thermophila ribosomal DNA minichromosome.

Two-dimensional gel electrophoresis was used to study replication of the Tetrahymena thermophila ribosomal DNA (rDNA) minichromosome. During vegetative growth, the rDNA is replicated exclusively from origins in the 5' nontranscribed spacer (NTS). Whereas replication fork movement through the rest of the chromosome appears to be continuous, movement through the 5' NTS is not. Replication forks arrest transiently at three prominent replication fork pausing sites (RFPs) located in or immediately adjacent to nucleosome-free regions of the 5' NTS. Pausing at these sites is dramatically diminished during replication in Escherichia coli, suggesting that chromatin organization or Tetrahymena-specific proteins may be required. A conserved tripartite sequence was identified at each pausing site. Mutations in type I elements diminish pausing at proximal RFPs. Hence, type I elements, previously shown to control replication initiation, also regulate elongation of existing replication forks. Studies with rDNA transformants revealed a strong directional bias for fork pausing. Strong pausing only occurred in forks moving toward the rRNA-coding region. We propose that fork pausing in the 5' NTS evolved to synchronize replication and transcription of the downstream rRNA genes.

Tetrahymena thermophila mutants defective in the developmentally programmed maturation and maintenance of the rDNA minichromosome.

The abundant rDNA minichromosome of Tetrahymena thermophila is generated by a series of developmentally controlled processing steps, termed rDNA maturation, during the formation of the new macronucleus in conjugating cells. rDNA maturation involves excision of a region encoding the single copy rRNA gene (rDNA) from its germline location, rearrangement of the rDNA into a palindromic minichromosome, de novo telomere addition, and amplification to approximately 10(4) copies. The rDNA is maintained at this high level in vegetatively growing cells. Using a previously developed genetic scheme for studying rDNA maturation and maintenance, we report the isolation of a new class of mutants defective for rDNA maturation. Several new rDNA maintenance mutants were also obtained. The maturation mutant, rmm10, is severely defective for the production of both monomeric and palindromic rDNA in the developing macronucleus. The mm10 mutation is recessive-lethal and cis-acting. None of the previously identified DNA sequence elements that control rDNA maturation or maintenance is mutated in rmm10. Therefore, additional cis-acting sequence elements must be required for rDNA maturation. Based on our current understanding of rDNA maturation processes, we suggest that the rmm10 mutation affects rDNA excision rather than subsequent rDNA amplification/replication.

A weak germ-line excision mutation blocks developmentally controlled amplification of the rDNA minichromosome of Tetrahymena thermophila.

During development of the somatic macronucleus of Tetrahymena thermophila, the rDNA is excised from its germ-line chromosome, rearranged into a palindrome, and amplified to 10(4) copies. We have identified a cis-acting germ-line mutation, rmm11/6, that prevents amplification of the rDNA in all but approximately 1 in 10(5) cells when it is the only rDNA allele in the developing macronucleus. The rmm11/6 mutation resides in a conserved element required for excision, the chromosome breakage sequence (Cbs) flanking the 3' end of the rDNA. Surprisingly, the rmm11/6 mutation only weakly affects excision of the rDNA from its germ-line location; at least 25% of cells heterozygous for this mutation correctly excise the affected rDNA allele. In heterozygotes, when this rDNA allele is excised, it is also poorly amplified. The rDNA amplification defect caused by this mutation is not overcome by delaying amplification with the DNA synthesis inhibitor aphidicolin, indicating that rDNA excision and amplification are not experimentally separable. Our experiments provide the first evidence that the capacity to amplify the rDNA is restricted in the developing macronucleus. We propose that the rmm11/6 mutation delays excision of the rDNA and that the developmental progression of the macronucleus past a restricted window for amplification is responsible for the severe amplification defect caused by this weak rDNA excision mutation.

Developmentally regulated processing and replication of the Tetrahymena rDNA minichromosome.

The ribosomal DNA locus of Tetrahymena thermophila undergoes a dramatic series of developmentally regulated processing events to generate the amplified rDNA minichromosome during formation of the somatic macronucleus. DNA transformation and classical genetic approaches have identified cis-acting elements that regulate rDNA processing in the developing macronucleus and subsequent vegetative rDNA maintenance.

Nuclease mapping and DNA sequence analysis of transcripts from the dihydrofolate reductase-thymidylate synthase (R) region of Leishmania major.

Trypanosomatid protozoan parasites utilize a number of nonstandard mechanisms in expressing their genes. To probe these phenomena in a genetically accessible system, we have mapped termini of eight transcripts arising from the amplified R region including the DHFR-TS gene of methotrexate-resistant Leishmania major. Poly(A)+ RNAs transcribed from the DHFR-TS-coding strand exhibit features similar to those observed around other trypanosomatid protein-coding genes. These include close spacing, the presence of a transpliced miniexon on the 5' termini, heterogeneity at both 5' and 3' ends, and in some cases S1 nuclease protection of intertranscript regions. Other than the splice acceptor site, no consensus sequence elements associated with either 5' or 3' ends were detected, although polydinucleotide tracts tended to be near inter-transcript regions. Two poly(A)+ RNAs transcribed from the opposite strand of the upstream flanking regions lacked the miniexon. Sequencing of DNA encoding the overlapping 1.7 kb opposite strand transcripts (one bearing and one lacking the miniexon, both found on polysomes) revealed no reading frames likely to encode proteins, suggesting that at least some of these RNAs could be nonfunctional by-products of RNA processing.

Stable transfection of the human parasite Leishmania major delineates a 30-kilobase region sufficient for extrachromosomal replication and expression.

To delineate segments of the genome of the human protozoan parasite Leishmania major necessary for replication and expression, we developed a vector (pR-NEO) which can be reproducibly introduced into L. major. This DNA was derived from a 30-kilobase extrachromosomal amplified DNA bearing the dihydrofolate reductase-thymidylate synthase gene, with the coding region for neomycin phosphotransferase substituted for that of dihydrofolate reductase-thymidylate synthase and a bacterial origin of replication and selectable marker added. G418-resistant lines were obtained at high efficiency by electroporation of pR-NEO (approaching 10(-4) per cell), while constructs bearing an inverted neo gene or lacking Leishmania sequences did not confer resistance. pR-NEO replicated in L. major and gave rise to correctly processed transcripts bearing the trans-spliced miniexon. Molecular karyotype analysis showed that in some lines pR-NEO DNA exists exclusively as an extrachromosomal circle, a finding supported by the rescue of intact pR-NEO after transformation of Escherichia coli. These data genetically localize all elements required in cis for DNA replication, transcription, and trans splicing to the Leishmania DNA contained within pR-NEO DNA and signal the advent of stable transfection methodology for addressing molecular phenomena in trypanosomatid parasites.

Transcriptional mapping of the amplified region encoding the dihydrofolate reductase-thymidylate synthase of Leishmania major reveals a high density of transcripts, including overlapping and antisense RNAs.

We have examined the transcriptional organization of the R region of the protozoan parasite Leishmania major. This region encodes the bifunctional enzyme dihydrofolate reductase-thymidylate synthase (DHFR-TS) and is frequently amplified as a 30-kilobase (kb) extrachromosomal circular DNA in methotrexate-resistant lines. Northern (RNA) blot analysis shows that the R region encodes at least 10 stable cytoplasmic polysomal poly(A)+ RNAs, ranging in size from 1.7 to 13 kb and including the 3.2-kb DHFR-TS mRNA. Transcriptional mapping reveals that these RNAs are closely spaced and collectively cover more than 95% of the 30-kb amplified R region. The organization is complex, including several overlapping RNAs 3' of DHFR-TS and two examples of antisense RNAs 5' of DHFR-TS. The R region RNAs can be grouped into two empirical domains, with eight contiguous RNAs transcribed in the same direction as that of DHFR-TS and two contiguous RNAs transcribed in the orientation opposite to that of DHFR-TS. The two 5'-most RNAs of the DHFR-TS-containing domain overlap the RNAs transcribed from the opposite strand. These data are relevant to models of transcription, including recent studies suggesting polycistronic transcription in trypanosomatids. The abundance of R region RNAs increases uniformly 10- to 15-fold in the amplified R1000-3 line relative to the wild type, and no new RNAs were observed. This suggests that all elements required in cis for DHFR-TS expression are contained within the 30-kb circular DNA. Quantitative analysis reveals that the steady-state DHFR-TS mRNA and protein levels are not growth phase regulated, unlike the monofunctional mouse DHFR. DHFR-TS is developmentally regulated, however, declining about fivefold in lesion amastigotes relative to promastigotes.

Sequence and S1 nuclease mapping of the 5' region of the dihydrofolate reductase-thymidylate synthase gene of Leishmania major.

The 5' structure of mRNA transcribed from the dihydrofolate reductase-thymidylate synthase (DHFR-TS) gene of the protozoan parasite Leishmania major has been characterized. S1 nuclease mapping identifies a heterogenous 5' structure which is not affected by growth phase or developmental stage. The DNA sequence of the 5' region of the DHFR-TS gene does not reveal homology with other trypanosomatid genes, eukaryotic consensus genetic elements, or the mammalian DHFR promoter element. This latter finding is especially significant as we show that the 5' region of the E. coli DHFR gene exhibits homology to the mammalian DHFR promoter element, despite their greater evolutionary distance.