The diagnostic value of the olfactory evaluation for congenital hypogonadotropic hypogonadism

Illuminating the terminal nerve: Uncovering the link between GnRH-1 neuron and olfactory development

During embryonic development, the olfactory placode (OP) generates migratory neurons, including olfactory pioneer neurons, cells of the terminal nerve (TN), gonadotropin-releasing hormone-1 (GnRH-1) neurons, and other uncharacterized neurons. Pioneer neurons from the OP induce olfactory bulb (OB) morphogenesis. In mice, GnRH-1 neurons appear in the olfactory system around mid-gestation and migrate via the TN axons to different brain regions. The GnRH-1 neurons are crucial in controlling the hypothalamic-pituitary-gonadal axis. Kallmann syndrome is characterized by impaired olfactory system development, defective OBs, secretion of GnRH-1, and infertility. The precise mechanistic link between the olfactory system and GnRH-1 development remains unclear. Studies in humans and mice highlight the importance of the prokineticin-2/prokineticin-receptor-2 (Prokr2) signaling pathway in OB morphogenesis and GnRH-1 neuronal migration. Prokr2 loss-of-function mutations can cause Kallmann syndrome (KS), and hence the Prokr2 signaling pathway represents a unique model to decipher the olfactory/GnRH-1 connection. We discovered that Prokr2 is expressed in the TN neurons during the critical period of GnRH-1 neuron formation, migration, and induction of OB morphogenesis. Single-cell RNA sequencing identified that the TN is formed by neurons distinct from the olfactory neurons. The TN neurons express multiple genes associated with KS. Our study suggests that the aberrant development of pioneer/TN neurons might cause the KS spectrum.

Mixed hypogonadism: a neglected combined form of hypogonadism

PURPOSE

Kallmann syndrome is a rare disease characterized by delayed puberty, infertility and anosmia. We report the clinical and genetic characteristics of three patients with Kallmann syndrome who presented with Klinefelter syndrome and defined this neglected combined form of hypogonadism as mixed hypogonadism.

METHODS

Clinical data and examinations were obtained, including laboratory examination and magnetic resonance imagination (MRI) of the olfactory structures. Congenital hypogonadotropic hypogonadism (CHH) related genes were screened by next generation sequencing (NGS).

RESULTS

Three patients with Kallmann syndrome were included. They had co-existence with Klinefelter syndrome and showed hypogonadotropic hypogonadism. Patient 1 was complicated with germinoma.

CONCLUSION

Mixed hypogonadism was defined as hypogonadotropic hypogonadism in Klinefelter syndrome or primary testicular disease. Clinicians should be alert to mixed hypogonadism when spermatogenesis induction failed in patients with CHH or gonadotropin levels decrease in patients with Klinefelter syndrome.

Illuminating the Terminal Nerve: Uncovering the Link between GnRH-1 and Olfactory Development

During embryonic development, the olfactory placode (OP) generates migratory neurons, including olfactory pioneer neurons, cells of the terminal nerve (TN), Gonadotropin-releasing hormone-1 (GnRH-1) neurons, and other uncharacterized neurons. Pioneer neurons from the olfactory placode induce olfactory bulb morphogenesis. In mice, GnRH-1 neurons appear in the olfactory system around mid-gestation and migrate via the terminal nerve axons to different brain regions. The GnRH-1 neurons are crucial in controlling the hypothalamic-pituitary-gonadal (HPG) axis. Kallmann syndrome is characterized by impaired olfactory system development, defective olfactory bulbs, defective secretion of GnRH-1, and infertility. The precise mechanistic link between the olfactory system and GnRH-1 development remains unclear. Studies in humans and mice highlight the importance of the Prokineticin-2/Prokineticin-Receptor-2 (Prokr2) signaling pathway in olfactory bulb morphogenesis and GnRH-1 neuronal migration. Prokr2 loss-of-function mutations can cause Kallmann syndrome, and hence the Prokr2 signaling pathway represents a unique model to decipher the olfactory/GnRH-1 connection. We discovered that Prokr2 is expressed in the TN neurons during the critical period of GnRH-1 neuron formation, migration, and induction of olfactory bulb morphogenesis. Single-cell RNA sequencing identified that the TN is formed by neurons that are distinct from the olfactory neurons. The TN neurons express multiple genes associated with KS. Our study suggests that the aberrant development of pioneer/TN neurons might cause the KS spectrum.

Key Points

1) Pioneer or terminal nerve neurons play a crucial role in initiating the development of the olfactory bulbs. We found that the Prokineticin Receptor-2 gene, associated with Kallmann syndrome, is expressed by the olfactory pioneer/terminal nerve neurons.2) We genetically traced, isolated, and conducted Single-cell RNA sequencing on terminal nerve neurons of rodents. This analysis revealed a significant enrichment of gene expression related to Kallmann syndrome.3) Our study indicates that the investigation of Pioneer/terminal nerve neurons should be a pivotal focal point for comprehending developmental defects affecting olfactory and GnRH-1 systems.

[Olfactory function and olfactory bulbs in patients with Kallmann syndrome]

BACKGROUND

The majority of Kallmann patients have anosmia or hyposmia. This is how the disease is diagnosed. Some of them don't have such complaints but olfactory dysfunction is diagnosed via olfactometry. Nowadays there is the lack of information about correlation between olfactometry results and subjective complaints. Correlation between olfactory bulbs size and olfactory dysfunction has been little studied.

AIM

To explore olfactory bulb size and olfactory function in patients with congenital isolated hypogonadotropic hypogonadism. To correlate olfactory bulb sizes and smell test scores.

MATERIALS AND METHODS

Single-centre comparative study. 34 patients were included. The main group consisted of 19 patients with hypogonadotropic (15 -with Kallmann syndrome, 4 - with normosmic hypogonadism). Olfactory bulbs MRI were provided to all the patients, olfactory test (Sniffin' Sticks Test) and molecular-genetic studies were provided in all patients with hypogonadism. Control group consisted of 15 patients who were provided with orbits MRI. Olfactory bulbs were evaluated additionally in them.

RESULTS

Normal size of olfactory bulbs were only in 1 patient with hypogonadism. Olfactory bulbs height and width were significantly smaller in patients with hypogonadism in comparison with control group (p<0.01). Height median of right bulb was 1.0 mm [0.2; 1.8] in patients from the main group vs. 3.0 [2.5; 3.2] in controls, width median of right bulb was 1.0 mm [0.2; 1.9] in patients from the main group vs. 2.5 [2.0; 3.0] in controls. Height median of left bulb was 0.8 mm [0.0; 1.2] in patients from the main group vs. 3.0 [2.7; 3.2] in controls, width median of left bulb was 0.8 mm [0.0; 1.2] in patients from the main group vs. 2.5 [2.0; 3.0] in controls. Correlation has been established between left bulb height (r=0.59) and width (r=0.67) and olfactometry results (p<0.05). 4 patients had no anosmia complaints but had olfactory dysfunction according to Sniffin' Sticks Tests.

CONCLUSION

Olfactometry was able to diagnose olfactory dysfunction in 78.5% (i.e. in 15 out of 19 patients with congenital isolated hypogonadotropic hypogonadism. However, anosmia complaints had only 11 out of 19 patients. It is the first results of olfactory bulb sizes in patients with hypogonadotropic hypogonadism in Russia. Uni - or bilateral hypoor aplasia were diagnosed in 94.7% patients with hypogonadism regardless of olfactory dysfunction. Bilateral olfactory bulbs hypoplasia were the most common MRI-finding (36.8%). Unilateral hypoor aplasia was diagnosed in 31.6% patients.