Receptor mechanisms of prenodal lymphatic constriction by dopamine.

It has been proposed that alterations in lymphatic smooth muscle activity significantly impact lymphatic function. Numerous endogenous vasoactive agents are known to constrict prenodal lymph vessels. In this study, we assessed the ability of dopamine to alter lymphatic smooth muscle tone in perfused prenodal lymph vessels. Additionally, the receptor mechanisms of dopamine's actions were elucidated. Both intralymphatic (i.l.) and intra-arterial (i.a.) dopamine significantly increased lymphatic perfusion pressure. The increase in lymphatic pressure was completely blocked by i.a. phentolamine, suggesting involvement of alpha(1)- and/or alpha(2)-adrenoreceptors. Intra-arterial infusion of the specific alpha(1)-receptor antagonist prazosin completely abolished the constriction seen during i.l. phenylephrine but only attenuated that produced by dopamine. Intralymphatic infusion of the DA(1)-receptor agonist SKF 82526-J and the DA(2)-receptor agonist LY 171555 caused significant relaxation of lymph vessels that had been previously constricted by i.a. norepinephrine infusion. These data indicate that the constriction produced by dopamine, in the concentrations employed in this study, is mediated by both alpha(1)- and alpha(2)-adrenoreceptors. These lymph vessels do contain both DA(1)- and DA(2)-receptors but stimulation of these receptors results in lymphatic smooth muscle relaxation.

Localization of the mutation responsible for osteopetrosis in the op rat to a 1.5-cM genetic interval on rat chromosome 10: identification of positional candidate genes by radiation hybrid mapping.

Osteopetrosis is caused by a heterogenous group of bone diseases that result in an increase in skeletal mass because of inadequate osteoclastic bone resorption. In the op osteopetrotic rat, the disease has been linked to a single genetic locus located at the proximal end of rat chromosome 10. In this study, we identified a 1.5-cM genetic interval that contains the mutation. We then generated an improved radiation hybrid (RH) map of this region to identify potential functional and positional candidates for the op gene. Using the rat genome radiation hybrid panel, we mapped 57 markers including 24 genes (14 that have not yet been mapped in the rat) and 10 expressed sequence tag markers. Included in the mapped genes are several candidate genes that might significantly influence the biochemical pathways involved in osteopetrosis. These include genes involved in osteoclast differentiation, apoptosis, and the functional capabilities of mature osteoclasts to resorb bone. Further analysis of the genes and expressed transcripts mapped to this region may yield important insights into the multifactorial control of osteoclast function and the mechanisms of failed bone homeostasis in diseases such as osteopetrosis, osteoporosis, and rheumatoid arthritis in which failed bone homeostasis is an instigating or exacerbating circumstance of the disease process.

Modulation of multiple experimental arthritis models by collagen-induced arthritis quantitative trait loci isolated in congenic rat lines: different effects of non-major histocompatibility complex quantitative trait loci in males and females.

OBJECTIVE: Collagen-induced arthritis (CIA) is a model of inflammatory arthritis with many similarities to rheumatoid arthritis (RA). We previously mapped in F(2) offspring of CIA-susceptible DA and CIA-resistant F344 rats, 5 quantitative trait loci (QTLs) for which F344 alleles were associated with reduced CIA severity. In the present study, we sought to characterize the independent arthritis-modulating effects of these 5 QTLs. METHODS: CIA-regulatory regions were transferred from the F344 genome to the DA background or vice versa by repeated backcrossing. The arthritis-modulating effects of the transferred alleles were determined by comparing the severity of experimentally induced arthritis in congenic rats with that in DA rats. RESULTS: Congenic lines with either the F344 major histocompatibility complex (MHC) on the DA background or the DA MHC on the F344 background were resistant to CIA, confirming both MHC and non-MHC contributions to the genetic regulation of CIA. F344 alleles at the Cia3 and Cia5 regions of chromosomes 4 and 10 reduced CIA severity relative to that observed in DA rats. F344 Cia4 and Cia6 regions of chromosomes 7 and 8 failed to significantly alter CIA severity. Arthritis-modifying effects of Cia4 and Cia6 were, however, detected in pristane-induced and/or Freund's incomplete adjuvant oil-induced arthritis. The arthritis-modifying effects of the non-MHC CIA-regulatory loci differed in males and females. CONCLUSION: These congenic lines confirmed the existence and location of genes that regulate the severity of experimental arthritis in rats. Mechanisms responsible for the sex-specificity of individual arthritis-regulatory loci may explain some of the sex differences observed in RA and other autoimmune diseases in humans.

Mutation of macrophage colony stimulating factor (Csf1) causes osteopetrosis in the tl rat.

Osteopetrosis results from a heterogeneous group of congenital bone diseases that display inadequate osteoclastic bone resorption. We recently mapped tl (toothless), a mutation that causes osteopetrosis in rats, to a genetic region predicted to include the rat Csf1 gene. In this study, we sequenced the coding sequence of the rat Csf1 gene to determine if a mutation in Csf1 could be responsible for the tl phenotype. Sequencing revealed a 10-base insertion in the coding sequence of mutant animals that produces a frameshift and generates a stop codon early in the mutant Csf1 coding sequence. The 41 amino acid polypeptide predicted to be produced from the Csf1 promoter would have only the first nine amino acids of the wild-type rat protein. These data suggest that osteopetrosis develops in tl/tl rats because they cannot produce functional mCsf, a growth factor required for osteoclast differentiation and activation.

Evaluation of quantitative trait loci regulating severity of mycobacterial adjuvant-induced arthritis in monocongenic and polycongenic rats: identification of a new regulatory locus on rat chromosome 10 and evidence of overlap with rheumatoid arthritis susceptibility loci.

OBJECTIVE: To evaluate the regulatory potential of genetic loci controlling Mycobacterium butyricum adjuvant-induced arthritis (Mbt-AIA) using mono- and polycongenic rats. METHODS: Of 4 quantitative trait loci (QTLs) that regulate Mbt-AIA, F344 alleles at 3 of these loci, Aia1, Aia2, and Aia3, are associated with lower arthritis severity, whereas F344 alleles at Aia4 are associated with greater arthritis severity. In this study, we constructed congenic lines by transferring 1 or more of the F344 genomic segments containing Aia1, Aia2, and Aia3 onto the DA genome. We comparatively evaluated their responses to Mbt-AIA with the responses of parental DA and F344 rats. RESULTS: Aia1, encompassing the rat major histocompatibility complex, reduced arthritis severity in monocongenic rats of both sexes. The arthritis-lowering effects of Aia2 and Aia3 were sex-influenced and were therefore observed in only males and only females, respectively. Polycongenic rats containing F344 genomic regions at Aia1, Aia2, and Aia3 developed Mbt-AIA of relatively greater severity than did F344 rats, implying that in DA and F344 rats, there could be other Mbt-AIA loci in addition to Aia1, Aia2, Aia3, and Aia4. To test the possibility that some of these Mbt-AIA-regulatory loci may colocalize with other arthritis QTLs, we evaluated Mbt-AIA in DA.F344 monocongenic rats containing collagen-induced arthritis QTLs. Cia5 (the QTL region on chromosome 10), but not Cia5a, Cia4, or Cia6, also regulated Mbt-AIA, and was named Aia5. CONCLUSION: F344 genomic regions at Aia1, Aia2, and Aia3 and the newly identified Aia5 contain genes that reduce Mbt-AIA severity in DA rats. These Mbt-AIA-regulatory loci overlap rheumatoid arthritis-susceptibility loci in humans.