The chromogranin/secretogranin family consists of a group of proteins derived from different genes but sharing a number of characteristics:

• (1)

  Phylogenetic. Significant interspecies gene homology.

• (2)

  Functional. Chromogranins are co-stored with molecules contained in dense secretion granules and are co-secreted by exocytosis by the regulated pathway. Unlike the constitutive secretion pathway, found in all cell types and characterized by the fact that recently synthesized proteins are transported by the cell using secretory vesicles for their immediate release without the need for a stimulus, the regulated pathway is characterized by its presence in more specialized cells (neuronal, endocrine, neuroendocrine, and polymorphonuclear neutrophils1) and by dense-core secretory granules, which is the name given to secretory vesicles in this pathway. These granules are characterized by:

  • (a)

    a maturation process consisting of the condensation and aggregation of protein material and the application of a specific coating in the presence of an acid and calcium-rich environment;

  • (b)

    a condensed charge of biogenic amines, hormone peptides, nucleotides, neurotransmitters, growth factors, and calcium (depending on cell type);

  • (c)

    strong staining with silver;

  • (d)

    electron-dense appearance in electron microscopy, and

  • (e)

    the ability to remain in the cell for periods of time, being released only in response to a stimulus which is specific to each cell type, both in normal and tumor cells.

• (3)

  Structural. They are water soluble, thermostable, acidic glycoproteins (due to the presence of abundant residues of acidic amino acids, glutamic acid and aspartic acid) with a sequence of 8–10 pairs of basic amino acids fairly preserved between species, which represent potential protease cleavage sites and bind to calcium with a low affinity but a high capacity.2–4 The initial protein is processed into smaller peptides in the intragranular milieu by proprotein convertase PC1/3, PC2, cathepsin,5,6 and to a lesser extent in the extracellular milieu by enzymes such as plasmin.7 Processing is different depending on cell type and is preserved despite tumoral transformation of the cell.8,9

The first member of this family to be isolated was chromogranin A, in 1965, from chromaffin cells of bovine adrenal medulla.10 Subsequently, chromogranin B was described in rat pheochromocytoma,11 and secretogranin II in bovine adenohypophysis.12

The main members of this family are chromogranin A (CgA, sometimes called parathyroid secretory protein), chromogranin B (CgB, sometimes called secretogranin I), and secretogranin II (sometimes called chromogranin C [CgC]).12–18 Other members of the family include secretogranin III (or 1B1075), IV (or HISL-19), V (or neuroendocrine protein 7B2), VI (or NESP55), and VII (or VGF).19

The granin family is widely expressed in different cells:

• -

  Neuronal cells of the peripheral and central nervous system (cerebellum, brain cortex, hypothalamus, hippocampus, amygdala and, possibly, in astroglial cells).

• -

  Endocrine cells (from the adrenal medulla, adenohypophysis, pancreas, gastrointestinal tract diffuse system, parathyroid glands, parafollicular or C cells of the thyroid gland, and bronchopulmonary cells).

• -

  Neuroendocrine differentiation cells (prostate, spleen, thymus, heart, breast, placenta).

• -

  In inflammatory sites in neutrophils.

The different members of the granin family have however different distributions. Thus, while CgA is predominately located in the adrenal medullar, gastrointestinal tract, and adenohypophysis, secretogranin II predominates in gonadotroph cells and pancreatic alpha cells.20–22

The presence of CgA in neuroendocrine cells has traditionally been described as ubiquitous, but its concentration varies depending on the type of tissue. Sympathoadrenal chromaffin cells are the main production and storage sites, followed in descending order by the adenohypophysis, pancreas, stomach, small bowel (jejunum and ileum), frontal cerebral cortex, parathyroid glands, and thyroid gland.22

When speaking of CgA we usually refer to the 439-amino acid proprotein CgA with a molecular weight of 48kDa, derived from pre-CgA (a 457-amino acid preprotein) and whose gene is located at the 14q32.12 locus. As previously discussed, CgA acts as a prohormone, and after undergoing post-translational changes such as glycosylation, phosphorylation, or sulfation and/or tissue-specific proteolytic processing, gives rise to biologically active peptides controlling multiple physiological roles. Most roles consist of direct or indirect inhibitory regulation through autocrine, paracrine, or endocrine pathways (Table 1).

While the role of CgA is not fully known, the role of its derived peptides is increasingly known,23–30 and it appears that many of the roles initially attributed to CgA, particularly extracellular functions, are actually mediated by these peptides (Table 2).

Different test methods are available for measuring CgA. The most widely known include CgA-RIA (CIS bio international), DAKO CgA ELISA, and CgA by IRMA (a sandwich method with dual antibody against the fractions of 145–197 and 198–245 amino acids). Stridsberg et al., in a study comparing three commercial methods (RIA, IRMA, and ELISA), found differences in specificity, sensitivity, and positive and negative predictive value. RIA, using a monoclonal antibody, was found to be the most sensitive method, while IRMA, using two monoclonal antibodies, was the most specific method.42

A Spanish study compared the different methods of measuring CgA in 52 healthy subjects, 98 patients with benign conditions, 94 patients with tumor (not neuroendocrine) pathology, 20 patients with small cell lung cancer, and 79 patients with neuroendocrine tumors (NETs). Using the different cut-off normal values (6nmol/L, 60ng/mL and 90ng/mL for RIA, ELISA and IRMA respectively) abnormal values were found in a high proportion of patients with renal failure (76.7, 86.7 and 93.3% with ELISA, IRMA, and RIA respectively), other benign diseases (chronic gastritis, inflammatory bowel disease, liver disease, and heart failure), and other tumoral diseases (59.8% ELISA; 55.4% IRMA; and 37% RIA). The ROC curves comparing the area under the curve between healthy subjects and patients with NETs, or between subjects with no NET (excluding those with renal failure and small cell lung cancer) or with NET showed better results with ELISA (0.96 and 0.77) and IRMA (0.95 and 0.78) as compared to RIA (0.80 and 0.69).43

Several factors may account for the differences found in these studies:

• -

  In each kit, the antibody is obtained from CgA molecules of different origin and size (CgA from Escherichia coli, CgA from urine of patients with carcinoid tumors)

• -

  CgA levels are expressed in different units (nmol/L, ng/ML, U/L) and the definition of the concentration considered as the upper normal limit is also different.

• -

  Differences between the antibodies used. The higher the number of epitopes in the CgA molecule that may be detected by an antibody, the greater its capacity to detect peptides derived from proteolytic processing of CgA and the more sensitive the method.

• -

  Differences in patient study sample as regards type of NET may bias the results, because the processing of whole molecule CgA is different in each tissue.

CgA levels may be measured in plasma or serum. There is a positive linear association between both methods (r=0.9858; p<0.001).44 CgA studies in saliva to quantify stress level are available, but this method has not been used to study NETs.45

There are multiple causes of CgA elevation inducing false positive CgA measurements: drugs (proton pump inhibitors, H2 receptor antagonists), renal failure, high blood pressure, heart failure, acute coronary syndrome, hyperthyroidism and hyperparathyroidism, chronic atrophic gastritis (CAG), pancreatitis, inflammatory bowel disease, irritable colon, chronic hepatitis and liver cirrhosis, rheumatoid arthritis, chronic bronchitis, and exercise-induce stress (Table 3). High CgA levels have also been reported in giant cell arteritis, rheumatoid arthritis, and systemic lupus erythematosus.46 One of the most common causes of false positive results is the use of proton pump inhibitors. Hypergastrinemia caused by these drugs due to acid secretion inhibition represents a stimulus for gastric enterochromaffin cells. The elevation is greater in patients treated for longer than one year.47 We are of the opinion that, since the optimum discontinuation time of such drugs has not been shown, they should be withdrawn at least 14–10 days before CgA measurement. They may be replaced by ranitidine (which should be discontinued three days before) or other antacids.

Unlike CgA, CgB is not affected by the presence of renal failure or the use of proton pump inhibitors. This may make CgB a supplemental tumor marker, but it should be taken into account that it has a different tissue expression pattern and that limitations and differences regarding the procedure used and definition of the upper normal limit also exist in its measurement. In a study on 44 patients with carcinoid tumors, 17 with sporadic endocrine tumors of the pancreas (ETPs) and 11 with ETPs associated with multiple endocrine neoplasia type 1 (MEN 1), CgB sensitivity was 87%, as compared to 99% for CgA.18,48–50

Elevated CgA levels have been found in a variety of NETs, including pheochromocytoma, paraganglioma, neuroblastoma, Merkel cell skin carcinoma, gastrointestinal NETs, pancreatic islet cell tumors, medullary thyroid carcinoma, adenomas of the parathyroid glands and adenohypophysis, and also in a proportion of patients with bronchopulmonary NETs (including small cell lung cancer).

As a tumor marker, serum CgA is characterized by being moderately sensitive and non-specific. In addition, among general (and non-specific, such as neuron-specific enolase, carcinoembryonic antigen (CEA), or human chorionic gonadotrophin) tumor markers, CgA has the greatest sensitivity and specificity for detecting NETs.51–53

CgA is of great value in NETs where no marker is available or symptoms occur late in the course of the disease, in nonfunctioning NETs, which usually retain the ability to secrete CgA, and in NETs where limitations (such as fluctuations in serum catecholamine levels in pheochromocytoma) or disadvantages (such as 24-hour urine collection after dietary restrictions) exist in measurements of the marker, representing in these cases a more stable marker.54

In a sample of 211 patients with NETs, both gastroenteropancreatic (GEP-NETs) and other types, whose serum CgA levels were measured by polyclonal RIA (using human CgA from pheochromocytomas as tracer), with 175mcg/L for men and premenopausal women and 220mcg/L for postmenopausal women being considered as upper normal limits, the proportions of patients showing high CgA levels per type of NET were, in descending order: gastrinoma (100%, n=9), pheochromocytoma (89%, n=9), carcinoid tumors (80%, n=62), nonfunctioning ETPs (69%, n=13), medullary thyroid carcinoma (50%, n=26), small cell lung carcinoma (39%, n=23), neuroblastoma (33%, n=3), Merkel cell tumor (25%, n=4), nonfunctioning pituitary adenomas (20%, n=10), insulinoma (10%, n=21), and paraganglioma (8%, n=25). In this sample, CgA levels expressed as median (range) in mcg/L were found to be highest in carcinoid tumors, 688 (33–52340) mcg/L, followed in descending order by gastrinoma, 772 (289–1933) mcg/L; nonfunctioning EPTs, 306 (85–14750) mcg/L; pheochromocytoma, 275 (110–4674) mcg/L; medullary thyroid carcinoma, 184 (80–13900) mcg/L; small cell lung carcinoma, 149 (45–2948) mcg/L; neuroblastoma, 133 (117–238) mcg/L; Merkel cell tumor, 109 (84–1056) mcg/L; paraganglioma, 106 (50–11590) mcg/L; insulinoma, 105 (63–236) mcg/L; nonfunctioning pituitary adenomas, 131 (85–240) mcg/L; and GH-secreting pituitary adenomas, 71 (53–115) mcg/L.53,55

Differences between tumors may be explained by the fact that circulating CgA expression depends on a number of factors such as cell type of origin, degree of differentiation, density of secretory granules, tumor size and extension, and tissue secretion capacity. As regards the last factor, it should be noted that high CgA levels appear to be significantly and independently associated with the presence of other secretions.56

CgA is the most abundant granin in GPE-NETs and represents the best general marker in tissue (together with synaptophysin for immunohistochemical confirmation) and blood.

The variability in sensitivity (60%–100%) and specificity (70%–100%) ranges for circulating CgA reported in the literature for the different types of GEP-NETs depends on several factors:

• -

  The clinical presentation of NETs, which depends in turn on the site of origin, histological tumor characteristics, primary tumor size, the route of dissemination, the presence or absence of metastases, the functionality or secretory activity of the tumor, the degree of neuroendocrine differentiation, and association with a hereditary syndrome.

• -

  The procedure used for measurement and whether it is able to detect peptides resulting from the fragmentation process.

• -

  The threshold considered as pathological, and how CgA variability is managed and studied in the control group of studies.

• -

  Its ubiquity in normal tissue, which causes different physiological or non-neoplastic pathological events to be also able to increase it.

The monitoring of CgA levels is helpful in patients with MEN 1 because it allows for the early diagnosis of GEP-NETs and, thus, for early treatment. The identification of elevated CgA levels suggests the presence of an ETP (in general) and, to a lesser extent, a gastrinoma, because primary hyperparathyroidism and/or pituitary adenoma rarely increase such levels.

For pancreatic NET screening, although CgA has been shown to be the most sensitive NET marker, it cannot be the only diagnostic measure, and CgA measurement should be combined with regular imaging tests. In a study in 34 patients with MEN 1 where CgA was measured by RIA using an upper normal limit of 130mcg/L, high CgA levels indicated the presence of a pancreatic tumor with 100% specificity, but only 59% sensitivity.62,82

• -

  Pheochromocytoma. CgA is helpful in the diagnosis and follow-up of pheochromocytoma for monitoring both treatment and tumor recurrence and progression. The isolated measurement of circulating CgA has a similar sensitivity and specificity to the measurement of catecholamines/metanephrines in plasma and urine, and it seems that a combination of both tests could increase yield. In addition, unlike as occurs with catecholamines, CgA measurement is not limited by fluctuations in serum levels. CgA levels decrease rapidly after surgery, while urinary catecholamine/metanephrine levels may take 2–3 weeks to decrease, and measurement is not altered by drugs for treatment. Serum CgA levels correlate with tumor size and extension, so that its value for screening patients with hereditary disease or small tumors is limited. The results regarding its role in discriminating between benign and malignant pheochromocytoma are controversial. In adrenal cortex tumors, CgA may be useful for differential diagnosis with poorly differentiated pheochromocytomas showing no catecholamine/metanephrine elevation.3,83–86

• -

  Other neoplasms derived from chromaffin cells. As previously shown, sensitivity in paraganglioma and neuroblastoma is low (10% and 30% respectively) as compared to sensitivities higher than 85% in pheochromocytoma reported in several studies.53 However, in a study in 34 children diagnosed with neuroblastoma (in different stages), CgA, as measured by RIA with values higher than 42ng/mL being considered the upper normal limit, had a diagnostic value with 91% sensitivity and 100% specificity with correlation with tumor size and was reported to be a helpful predictor of survival.87

• -

  Medullary thyroid carcinoma. The measurement of circulating CgA for the diagnosis of this tumor is not superior to calcitonin (CT) or CEA, except for dedifferentiated tumors that do not express CT or CEA.88

• -

  Pituitary adenomas. Conflicting results have been reported for CgA in the diagnosis of gonadotropinoma, clinically nonfunctioning pituitary adenomas, and non-endocrine pituitary tumors.53,89,90 Its value for the etiological diagnosis of Cushing's syndrome has been pointed out, suggesting that high concentrations may indicate an ectopic origin.91 As in pheochromocytoma, it seems that the measurement of CgB and secretogranin II may have a diagnostic value in prolactinoma.3

• -

  Parathyroid neoplasms. CgA does not appear to be of any value.

Elevated CgA levels in other tumors reflect their neuroendocrine differentiation in patients with pancreatic, colorectal, gastric, and prostate cancer. In breast carcinoma and hepatocarcinoma, the cause of such elevation is not clear.

In patients with adenocarcinoma of the pancreas, higher levels are found as compared to those with chronic pancreatitis and healthy subjects.92

CgA may be elevated in up to 34% of patients with colorectal cancer and is related to poorer prognostic after surgery.93

In prostate cancer, a correlation exists between immunohistochemistry and plasma levels, and CgA it has also been related to Gleason stage and unfavorable prognosis.94,95 Moreover, CgA measurement may help identify patients with advanced prostate cancer with no elevated prostate-specific antigen levels, those who could be eligible for adjuvant therapy, or those resistant to hormone suppression therapy.96 These are some of the factors leading to routine CgA measurement in clinical practice in the management of adenocarcinoma and mixed tumors of the prostate.

High CgA levels are found in more than 80% of patients with hepatocarcinoma, in which higher elevations are seen as compared to chronic hepatitis and liver cirrhosis.

The authors state that they have no conflicts of interest.