Synthesis and characterization of novel biotinylated carboxyl-terminal parathyroid hormone peptides that specifically crosslink to the CPTH-receptor

Parathyroid hormone (PTH) regulates calcium, phosphorous and skeletal homeostasis via interaction with the G protein-coupled PTH/PTHrP receptor, which is fully activated by the amino-terminal 34 amino-acid portion of the hormone. Recent evidence points to the existence of another class of receptors for PTH that recognize the carboxyl (C)-terminal region of intact PTH(1–84) (CPTHRs) and are highly expressed by osteocytes. Here we report the synthesis and characterization of two novel bifunctional CPTH ligands that include benzoylphenylalanine (Bpa) substitutions near their amino-termini and carboxyl-terminal biotin moieties, as well as a tyrosine(34) substitution to enable radioiodination. These peptides are shown to bind to CPTHRs with affinity similar to that of PTH (1–84) and to be specifically and covalently cross-linked to CPTHRs upon exposure to ultraviolet light. Crosslinking to osteocytes or osteoblastic cells generates complexes of 80kDa and 220kDa, of which the larger form represents an aggregate that can be resolved into the 80kDa. The crosslinked products can be further purified using immunoaffinity and avidin-based affinity procedures. While the molecular structure of the CPTHR(s) remains undefined, these bifunctional ligands represent powerful new tools for use in isolating and characterizing CPTHR protein(s)

Functional Analysis of a Type 1 Parathyroid Hormone Receptor Intracellular Tail Mutant [KRK(484-6)AAA]: Effects on Second Messenger Generation and Cellular Targeting

The parathyroid hormone receptor type 1 (PTHR1) is activated by parathyroid hormone (PTH) and PTH-related protein (PTHrP) and primarily signals via intracellular pathways involving adenylyl cyclase and phospholipase C. The intracellular tail domain of the PTHR1 contributes to G protein subunit coupling that is important for second messenger signalling. In addition, the intracellular domain has a potential nuclear localization sequence (NLS) that, if functional, could point to an intracrine role for the receptor. In the present study, we have utilized 2 sets of constructs that employ either a [KRK(484-486)AAA](3Ala) mutation in the putative NLS or the non-mutant counterpart and included (a) the full-length rat PTHR1 with FLAG and c-myc epitope tags at the N-terminus and C-terminus, respectively (designated as PTHR1(3Ala)-TAG and PTHR1-TAG); and (b) only the putative NLS-containing intracellular domain (471-488), with green fluorescent protein (GFP) fused to the C-terminus (designated as GFP-(3Ala)471-488 or GFP-471-488). Porcine kidney LLC-PK1 cells stably expressing the PTHR1(3Ala)-TAG exhibited reduced signalling via both cAMP and cytosolic calcium transients in spite of greater cell surface expression relative to cells expressing PTHR1-TAG. We also examined the ability of the intracellular tail to influence the cellular localization of a heterologous protein. LLC-PK1 cells transiently transfected with GFP-471-488, exhibited increased fluorescence within the nucleus, relative to cells transfected with GFP alone that was not observed when cells were transiently transfected with the mutated construct, GFP-(3Ala)471-488. However, LLC-PK1 cells transiently transfected with either the full-length PTHR1-TAG or the PTHR1(3Ala)-TAG constructs did not exhibit nuclear localization of these receptors. Moreover, mouse osteoblast-like cells (MC3T3-E1) transiently expressing PTHR1-TAG also failed to demonstrate nuclear localization, although both full-length PTHR1 constructs exhibited plasma membrane immunofluorescence in both cell lines. Thus, the 484-486 sequence is critical for the full signalling responsiveness of the intact PTHR1, but the putative nuclear localization signal may not function as such within the intact receptor

CBP/p300-Interacting Protein CITED1 Modulates Parathyroid Hormone Regulation of Osteoblastic Differentiation

PTH regulates osteoblastic differentiation and activity and exerts different overall skeletal effects in vivo, depending on the schedule and dose of administration. In clonal Wt9 murine osteoblastic cells, mRNA and protein levels of CITED1 transcriptional coactivator were strongly up-regulated by human (h) PTH(1–34). Stimulation of CITED1 mRNA by PTH was transient, peaking at 4 h, concentration dependent, and blocked by actinomycin D but not cycloheximide. The stimulation was mimicked by forskolin, phorbol ester, and the cAMP-selective PTH analog [G1,R19] hPTH (1–28) and inhibited completely by the protein kinase A inhibitor, H89 and partially by phorbol ester-induced protein kinase C depletion. Increased CITED1 expression was not maintained during persistent (24 h) PTH exposure. Cultured primary calvarial osteoblasts from neonatal homozygous or hemizygous CITED1-knockout (KO) mice achieved 2-fold greater mineralized nodule formation in comparison with wild type (WT) osteoblasts. This effect was blocked by restoration of CITED1 expression via adenoviral gene transfer. Intermittent administration of hPTH(1–34) (10 nm, for 4 h every 48 h) for 3–6 wk increased mineralization up to 2-fold over basal levels in both WT and CITED1 KO mouse calvarial cell cultures. Whereas the cAMP-selective [G1,R19]hPTH(1–28) analog [at 100 nm, equivalent to 10 nm hPTH(1–34)] did not stimulate mineralization in WT cultures, it was twice as effective as hPTH(1–34) in CITED1 KO cultures. Thus, CITED1 negatively regulates osteoblastic differentiation in vitro and inhibits the cAMP-dependent stimulation of differentiation by intermittent PTH. We conclude also that PTH receptor signaling pathways independent of cAMP restrain osteoblastic differentiation, an effect normally obscured in the presence of CITED1 but revealed in its absence