Bone remodeling markers and bone cancer

Abbreviations

BAP

Serum bone alkaline phosphatase

BMD

Bone mineral density

BSP

Bone sialoprotein

CTX-I

Epitope of C-terminal cross-linked telopeptide of collagen type I

DPD

Deoxypyridinoline

ICTP

Epitope of C-terminal cross-linked telopeptide of collagen type I

LSC

Least significant change

MGUS

Monoclonal gammopathy of undetermined significance

NSCLC

Non–small cell lung cancer

NTX-I

N-terminal cross-linked telopeptide of collagen type I

OC

Osteocalcin

PICP

C-terminal propeptide of procollagen type I

PINP

N-terminal propeptide of procollagen type I

PSA

Prostate-specific antigen

PYD

Pyridinoline

RANKL

Receptor activator of NFkappaB ligand

RTM

Regression to the mean

TAP

Serum total alkaline phosphatase

TRAcP

Tartrate-resistant acid phosphatase

Chapter for: Heymann (ed.): ‘Recent Advances in Bone Cancer: Progression and Therapeutic Approaches'. Updated version May 2020

Introduction

Bone metastases are frequent and seen in many malignancies, but preferentially occur in patients with breast, prostate, thyroid, kidney, bladder, and lung cancers. Although usually not lethal in themselves, bone metastases often cause refractory pain, hypercalcemia, fractures, neurological symptoms, and, as a result, profound morbidity and a reduction in quality of life [ ]. Over 60% of breast cancer patients with skeletal metastasis have skeletal complications, averaging to four such events per year [ ]. Of note, newer bisphosphonates significantly reduce the rate of skeletal events in cancer patients, particularly when used during early disease stages [ ]. Consequently, there is a clear clinical requirement to identify patients with bone metastases as early as possible, and to develop sensitive and specific means to monitor treatment efficacy and predict outcomes.

The diagnostic approach to metastatic bone disease traditionally focuses on the localization and characterization of the lesion, employing an array of different imaging techniques such as radiographs, CT, MRI, (quantitative) ⁹⁹ Tc bone scans, and positron emission tomography (PET). All of these procedures are of value in case-finding studies, where the goal is to identify patients with established metastatic spread. At earlier stages of the disease process, however, changes in skeletal morphology or radionuclide uptake may be discrete, nonspecific, or completely absent. Also, not all imaging techniques are equally well suited for the monitoring of skeletal disease progression or therapeutic response, particularly in patients with short survival times. Tumor markers such as PSA closely correlate with the extent of neoplastic tissue and may therefore be useful in the clinical monitoring of tumor behavior and treatment response [ ]. With scant exceptions, however, these markers do not provide information specific to the skeleton's involvement.

Under normal conditions, the process of bone remodeling is a balanced, lifelong continuum of resorbing old bone (through the action of osteoclasts) and replacing the removed tissue by an equal amount of newly formed bone (through the action of osteoblasts). The presence of cancer cells within the bone microenvironment greatly perturbs this balance. Thus, most osteolytic cancers are known to secrete cytokines and other factors (such as PTHrP), which induce osteoblasts and osteocytes to release RANKL. This potent cytokine activates osteoclasts to resorb bone, which not only provides space for the tumor to expand into, but also causes, the release of growth factors from the bone matrix, which in turn support and induce further tumor growth [ , ]. Bone formation rates can vary but are usually inadequate to compensate for the tumor-driven escalation in bone resorption. Radiographically, these changes result in predominantly lytic or mixed lytic–sclerotic lesions, as typically seen in breast cancer metastases to bone. In contrast, prostate cancers often cause sclerotic lesions characterized at the cellular level by a relative excess of bone formation compared to bone resorption. However, even the skeletal metastases of prostate cancer are characterized by an increase in the rate of both bone resorption and formation. High bone turnover with excess bone resorption therefore is an archetypal feature of most, if not all bone metastases. The cellular mechanisms associated with bone metastasis are covered in Chapters of Part 1, Section 2 in this volume and have also been reviewed in Refs. [ ].

Biochemical markers of bone turnover ( Fig. 30.1 ) are noninvasive and relatively inexpensive tools that, if applied and interpreted correctly, can be effectively used in assessing changes in bone remodeling associated with metastatic bone disease. Table 30.1 summarizes the biological and technical details of the currently used bone markers. For an in-depth review of the basic biochemistry of bone markers, please refer to Refs. [ ].

Figure 30.1, Biochemical markers of bone remodeling.

Table 30.1

Markers of bone turnover.

Marker (Abbreviation)	Tissue	Specimen		Method	Remarks
Markers of bone formation
Bone-specific alkaline phosphatase (BAP)	Bone	Serum		Electro-phoresis, Precipita-tion, IRMA, EIA	Specific product of osteoblasts. Some assays show up to 20% cross-reactivity with liver isoenzyme (LAP).
Osteocalcin (OC)	Bone, platelets	Serum		RIA, IRMA, ELISA	Specific product of osteoblasts; many immunoreactive forms in blood; some may be derived from bone resorption.
C-terminal propeptide of type I procollagen (PICP)	Bone, soft tissue, skin	Serum		RIA, ELISA	Specific product of proliferating osteoblasts and fibroblasts.
N-terminal propeptide of type I procollagen (PINP)	Bone, soft tissue, skin	Serum		RIA, ELISA	Specific product of proliferating osteoblast and fibroblasts; partly incorporated into bone extracellular matrix.
Markers of bone resorption
Collagen-related markers
Hydroxyproline, total and dialyzable (Hyp)	Bone, cartilage, soft tissue, skin		Urine	Colorimetry HPLC	Present in all fibrillar collagens and partly collagenous proteins, including C1q and elastin. Present in newly synthesized and mature collagen, i.e., both collagen synthesis and tissue breakdown contribute to urinary hydroxyproline.
Hydroxylysine glycosides	Bone, soft tissue, skin, serum complement		Urine (serum)	HPLC ELISA	Hydroxylysine in collagen is glycosylated to varying degrees, depending on tissue type. Glycosylgalactosyl-OHLys in high proportion in collagens of soft tissues, and C1q; Galactosyl-OHLys in high proportion in skeletal collagens.
Pyridinoline (PYD)	Bone, cartilage, tendon, blood vessels		Urine Serum	HPLC ELISA	Collagens, with highest concentrations in cartilage and bone, absent from skin; present in mature collagen only.
Deoxypyridinoline (DPD)	Bone, dentin		Urine Serum	HPLC ELISA	Collagens, with highest concentration in bone, absent from cartilage or skin; present in mature collagen only.
Carboxyterminal cross-linked telopeptide of type I collagen (ICTP, CTX-MMP)	Bone, skin		Serum	RIA	Collagen type I, with highest contribution probably from bone, may be derived from newly synthesized collagen.
Carboxyterminal cross-linked telopeptide of type I collagen (CTX-I)	All tissues containing type I collagen		Urine (a-/β) Serum (αα/ββ)	ELISA RIA	Collagen type I, with highest contribution probably from bone. Isomerization of aspartyl to β-aspartyl occurs with aging of collagen molecule.
Aminoterminal cross-linked telopeptide of type I collagen (NTX-I)	All tissues containing type I collagen		Urine Serum	ELISA CLIA RIA	Collagen type I, with highest contribution from bone.
Collagen I alpha 1 helicoidal peptide (HELP)	All tissues containing type I collagen		Urine	ELISA	Degradation fragment derived from the helical part of type I collagen (α1 chain, AA 620-633). Correlates highly with other markers of collagen degradation, no specific advantage or difference in regard to clinical outcomes.
Noncollagenous proteins
Bone sialoprotein (BSP)	Bone, dentin, hypertrophic cartilage		Serum	RIA ELISA	Acidic, phosphorylated glycoprotein, synthesized by osteoblasts and osteoclastic-like cells, laid down in bone extracellular matrix. Appears to be associated with osteoclast function.
Osteocalcin fragments (ufOC, U-mid-OC,U-LongOC)	Bone		Urine	ELISA	Certain age-modified OC fragments are released during osteoclastic bone resorption and may be considered an index of bone resorption.
Osteopontin (OPN)	Bone, kidney, placenta, dentin, cartilage, brain, muscle, blood vessels		Serum	ELISA	Synthesized by a variety of tissue types. Synthesis in bone is stimulated by 1,25-dihydroxy-vitamin D3.
Osteoclast enzymes
Tartrate-resistant acid phosphatase (TRAcP)	Bone Blood		Plasma, serum	Colorimetry RIA ELISA	Six isoenzymes found in human tissues (osteoclasts, platelets, erythrocytes). Band 5b predominant in bone (osteoclasts). Enzyme identified in both the ruffled border of the osteoclast membrane and the secretions in the resorptive space.
Cathepsins (e.g., K, L) (CathK, Cath L)	K: Primarily in osteoclasts L: Macrophage, osteoclasts		Plasma, Serum	ELISA	Cathepsin K, cysteine protease, plays an essential role in osteoclast-mediated bone matrix degradation by cleaving helical and telopeptide regions of collagen type I. Cathepsin K and L cleave the loop domain of TRAcP and activate the latent enzyme. Cathepsin L has a similar function in macrophages. Tests for measurement of cathepsins in blood are presently under evaluation.

This chapter focuses on the clinical application of biochemical markers of bone turnover in metastatic bone disease, with specific emphasis on the clinically important topics of diagnosis, prognosis, and therapeutic response monitoring. For information on the utility of cytokine/osteoclastogenesis-related markers such as RANKL, OPG, and interleukins in metastatic bone disease, please refer to Ref. [ ]. This recent consensus paper also contains information regarding the use of biochemical markers in malignant bone disease.

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