LHX3 and LHX4 transcription factors in pituitary development and disease.

The LHX3 and LHX4 LIM-homeodomain proteins are regulatory transcription factors that play overlapping but distinct functions during the establishment of the specialized cells of the mammalian pituitary gland and the nervous system. Recent studies have identified a variety of mutations in the LHX3 and LHX4 genes in patients with combined pituitary hormone deficiency diseases. These patients have complex and variable syndromes involving short stature, metabolic disorders, reproductive system deficits, and nervous system developmental abnormalities. The short stature secondary to growth hormone deficiency is a key feature of the disorders associated with these gene mutations and responds well to supplementation with recombinant growth hormone. Overall, the frequency of mutations in the LHX3 and LHX4 genes in patients with combined pituitary hormone deficiency is low. Mutations in other regulatory genes such as HESX1, PROP1, PIT1 / POU1F1, and GLI2 have been shown to be additional causes of pituitary hormone deficiency, but overall, the etiology of many cases of hypopituitarism is not understood. Further investigation is therefore required to identify other genes, both primary regulatory genes and those with modifier functions, which contribute to pituitary development and function.

Height gain with combined growth hormone and gonadotropin-releasing hormone analog therapy in two pubertal siblings with a growth hormone-releasing hormone receptor mutation.

CONTEXT: Patients with GHRH receptor (GHRH-R) mutations present with familial isolated GH deficiency, which untreated leads to a severely compromised adult height. Few data are available about the efficacy of treatment with GH in combination with a GnRH analog (GnRHa) in adolescence. OBJECTIVE: The objective of the study was to describe the evolution of growth and skeletal age of a brother and sister of Moroccan descent with a homozygous GHRH-R mutation who presented at an advanced age (16 and 14.9 yr, respectively) and pubertal stage (Tanner stage G4 and B3, respectively) with a height of -5.1 sd score and -7.3 sd score on treatment with a combination of GH and GnRHa for 2.5 and 3 yr followed by GH alone. METHODS: GH was given in a dosage of 0.7 mg/m2.d (25 microg/kg.d) sc and triptorelin in a dosage of 3.75 mg per 4 wk im. Height and pubertal stage were measured three-monthly, bone age yearly. RESULTS: Combined GH and GnRHa treatment resulted in a height gain of 24 and 28.2 cm, respectively, compared with the initial predicted adult height by the method of Bayley and Pinneau. Adult height was within the population range and well within the target range. CONCLUSIONS: Our patients demonstrate that, in case of isolated GH deficiency caused by a GHRH-R mutation, combined treatment of GH and GnRHa can be very effective in increasing final height, even at an advanced bone age and pubertal stage.

Three novel missense mutations within the LHX4 gene are associated with variable pituitary hormone deficiencies.

CONTEXT: The LHX4 LIM-homeodomain transcription factor has essential roles in pituitary gland and nervous system development. Heterozygous mutations in LHX4 are associated with combined pituitary hormone deficiency. OBJECTIVES: Our objectives were to determine the nature and frequency of LHX4 mutations in patients with pituitary hormone deficiency and to examine the functional outcomes of observed mutations. DESIGN: The LHX4 gene sequence was determined from patient DNA. The biochemical and gene regulatory properties of aberrant LHX4 proteins were characterized using structural predictions, pituitary gene transcription assays, and DNA binding experiments. PATIENTS: A total of 253 patients from 245 pedigrees with GH deficiency and deficiency of at least one additional pituitary hormone was included in the study. RESULTS: In five patients, three types of heterozygous missense mutations in LHX4 that result in substitution of conserved amino acids were identified. One substitution is between the LIM domains (R84C); the others are in the homeodomain (L190R; A210P). The patients have GH deficiency; some also display reductions in TSH, LH, FSH, or ACTH, and aberrant pituitary morphology. Structural models predict that the aberrant L190R and A210P LHX4 proteins would have impaired DNA binding and gene activation properties. Consistent with these models, EMSAs and transfection experiments using pituitary gene promoters demonstrate that whereas the R84C form has reduced activity, the L190R and A210P proteins are inactive. CONCLUSIONS: LHX4 mutations are a relatively rare cause of combined pituitary hormone deficiency. This report extends the range of phenotypes associated with LHX4 gene mutations and describes three novel exonic mutations in the gene.

Four novel mutations of the LHX3 gene cause combined pituitary hormone deficiencies with or without limited neck rotation.

CONTEXT: The Lhx3 LIM-homeodomain transcription factor gene is required for development of the pituitary and motoneurons in mice. Human LHX3 gene mutations have been reported in five subjects with a phenotype consisting of GH, prolactin, TSH, LH, and FSH deficiency; abnormal pituitary morphology; and limited neck rotation. OBJECTIVE: The objective of the study was to determine the frequency and nature of LHX3 mutations in patients with isolated GH deficiency or combined pituitary hormone deficiency (CPHD) and characterize the molecular consequences of mutations. DESIGN: The LHX3 sequence was determined. The biochemical properties of aberrant LHX3 proteins resulting from observed mutations were characterized using reporter gene and DNA binding experiments. PATIENTS: The study included 366 patients with isolated GH deficiency or CPHD. RESULTS: In seven patients with CPHD from four consanguineous pedigrees, four novel, recessive mutations were identified: a deletion of the entire gene (del/del), mutations causing truncated proteins (E173ter, W224ter), and a mutation causing a substitution in the homeodomain (A210V). The mutations were associated with diminished DNA binding and pituitary gene activation, consistent with observed hormone deficiencies. Whereas subjects with del/del, E173ter, and A210V mutations had limited neck rotation, patients with the W224ter mutation did not. CONCLUSIONS: LHX3 mutations are a rare cause of CPHD involving deficiencies for GH, prolactin, TSH, and LH/FSH in all patients. Whereas most patients have a severe hormone deficiency manifesting after birth, milder forms can be observed, and limited neck rotation is not a universal feature of patients with LHX3 mutations. This study extends the known molecular defects and range of phenotypes found in LHX3-associated diseases.

Mutations in the LHX3 gene cause dysregulation of pituitary and neural target genes that reflect patient phenotypes.

The LHX3 LIM-homeodomain transcription factor is required for correct development of the mammalian pituitary gland and spinal motoneurons. Mutations in the LHX3 gene underlie complex diseases featuring combined anterior pituitary hormone deficiency and, in specific cases, loss of neck rotation considered to result from nervous system abnormalities. The molecular basis for LHX3 protein actions in both normal and aberrant pituitary and nervous system development is poorly understood. In this study, the gene regulatory abilities of mutant LHX3 proteins associated with distinct types of diseases (LHX3a A210V, LHX3a E173Ter, and LHX3a W224Ter) were investigated. The capacity of these proteins to activate pituitary hormone and transcription factor gene promoters, nervous system target genes, and to localize to the nucleus of pituitary cells was measured. Consistent with the symptoms of patients with these mutations, the abnormal proteins displayed diminished capacities to activate the promoters of genes expressed in the pituitary gland. On nervous system promoters, several mutant proteins retained some activity. The ability of the mutant proteins to concentrate in the nucleus of pituitary cells was correlated with the retention of defined nuclear localization signals in the protein sequence, except for the E173Ter protein which unexpectedly localizes to the nucleus, likely due to the insertion of cryptic nuclear localization signals by a frame shift caused by the mutation. This study extends the molecular characterization of the severe neuroendocrine diseases associated with LHX3 gene mutations.

The growth response to growth hormone (GH) treatment in children with isolated GH deficiency is independent of the presence of the exon 3-minus isoform of the GH receptor.

CONTEXT: A variant of the human GH receptor (GHR) lacks a 22-amino-acid sequence derived from exon 3 (d3-GHR). It was reported that pediatric patients, born small for gestational age or with idiopathic short stature who were homozygous or heterozygous for this variant responded better to GH treatment than those homozygous for the full-length allele (fl-GHR). OBJECTIVE: The objective was to study the impact of the GHR genotype on the phenotype and growth response in patients with isolated GH deficiency (IGHD) treated with GH. DESIGN: This was a retrospective, multinational, multicenter observational study. PATIENTS: Patients with IGHD (n = 107) were recruited. INTERVENTIONS: All patients received GH treatment at replacement doses. The GHR genotype (fl-GHR/fl-GHR, fl-GHR/d3-GHR, or d3-GHR/d3-GHR) was determined by PCR amplification. MAIN OUTCOME MEASURES: Measures included height sd score, height velocity, height velocity sd score at baseline and 1 yr of GH treatment, and their changes. RESULTS: There was no statistically significant difference of the main outcome measures between patients with the d3-GHR allele (n = 48) and patients who were homozygous for the fl-GHR allele (n = 59). Moreover, the genotype group did not contribute significantly to the growth prediction in multiple linear regression models. CONCLUSIONS: Our results indicate that the d3-GHR allele does not affect response to GH treatment or contribute to growth predictions in patients with IGHD who received replacement doses of GH aiming to restore a normal GH status. We did not confirm the previously reported data obtained in patients small for gestational age or with idiopathic short stature who received supraphysiological GH doses.

Auxological and endocrine phenotype in a population-based cohort of patients with PROP1 gene defects.

OBJECTIVE: Multiple pituitary hormone deficiency (MPHD) may result from defects of transcription factors that govern early pituitary development. We aimed to establish the prevalence of HESX1, PROP1, and POU1F1 gene defects in a population-based cohort of patients with MPHD and to analyse the phenotype of affected individuals. DESIGN AND METHODS: Genomic analysis was carried out on 74 children and adults with MPHD from the Czech Republic (including four sibling pairs). Phenotypic data were collected from medical records and referring physicians. RESULTS: One patient carried a heterozygous mutation of POU1F1 (71C > T), and 18 patients (including three sibling pairs) had a PROP1 mutation (genotypes 150delA/301delGA/9/, 301delGA/301-delGA/8/, or 301delGA/349T > A/1/). A detailed longitudinal phenotypic analysis was performed for patients with PROP1 mutations (n = 17). The mean ( +/-s.d.) birth length SDS of these patients (0.12 +/- 0.76) was lower than expected based on their mean ( +/-s.d.) birth weight SDS (0.63 +/- 1.27; P = 0.01). Parental heights were normal. The patients' mean ( +/-s.d.) height SDS declined to -1.5 +/- 0.9, -3.6 +/- 1.3 and -4.1 +/- 1.2 at 1.5, 3 and 5 years of age, respectively. GH therapy, initiated at 6.8 +/- 3.2 years of age (mean dose: 0.022 mg/kg per day), led to substantial growth acceleration in all patients. Mean adult height (n = 7) was normal when adjusted for mid-parental height. ACTH deficiency developed in two out of seven young adult patients. CONCLUSIONS: PROP1 defects are a prevalent cause of MPHD. We suggest that testing for PROP1 mutations in patients with MPHD might become standard practice in order to predict risk of additional pituitary hormone deficiencies.

High prevalence of PROP1 defects in Lithuania: phenotypic findings in an ethnically homogenous cohort of patients with multiple pituitary hormone deficiency.

CONTEXT: PROP1 gene mutations cause multiple pituitary hormone deficiency (MPHD). OBJECTIVE: We sought to expand experience with PROP1 mutation carriers by studying a large cohort of Lithuanian patients. PATIENTS AND METHODS: Sixty-seven MPHD patients were tested for PROP1 defects. Perinatal and postnatal data were obtained from medical records. Hormonal investigations, pituitary imaging, and GH therapy were provided in a single center in Kaunas, Lithuania. RESULTS: A biallelic PROP1 gene mutation was found in 47 subjects (70.1%), of which 46 were homozygous for 296delGA. Positive finding rate among MPHD and population prevalence of PROP1 defects in Lithuania (15.8 per million) were the highest reported to date. Patients' birth lengths/weights were normal. Testicular retention was noted in 31% of boys. Median height SD scores declined over years 1-5: -1.56, -2.34, -3.43, -3.52, and -3.70. Mid-parental height predicted severity of growth retardation at diagnosis (r2=0.30; P=.0001). Deficiencies of GH, TSH, ACTH, and FSH/LH were diagnosed in 44/44, 44/44, 19/44, and 22/44 subjects at median age of 5.5, 5.6, 13.1, and 15.0 years, respectively. Pituitary height ranged from 16.6 mm (+20.2 SD) to 1.4 mm (-15.5 SD) and declined with age (r2=0.27, P=.001). GH replacement (dose 0.027 mg/kg/d) led to height velocities 12.2; 9.1; 6.9; 6.8; 6.7; 5.6; and 5.7 cm/y (medians) at years 1-7 and final height SD scores (17 patients) -0.98±1.77 (-1.04±1.41 below target height; P=.008 vs 0). CONCLUSIONS: High prevalence of PROP1 defects in Lithuania is due to 296delGA mutation, suggesting a founder effect.