V08_No_1_Print_3.pdf


Review

1Urology Journal   Vol 8   No 1   Winter 2011

Advanced Treatments in Non-Clear Renal Cell
Carcinoma
El Mehdi Tazi,1 Ismail Essadi,1 Mohamed Fadl Tazi,2 Youness Ahellal,2
Hind M’Rabti,1 Hassan Errihani1

Purpose: To focus on the use of targeted therapies against the non-clear 
histologic subtypes of renal cell carcinoma (RCC); papillary I and II, 
chromophobe, and collecting duct. The unique genetic and molecular profiles 
of each distinct non-clear kidney cancer subtype will be described, as these 
differences are integral to the development and effectiveness of the novel 
agents used to treat them.
Materials and Methods: On the basis of MEDLINE database searches, we 
assessed all aspects of targeted therapy in non-clear cell RCC between 2000 and 
2010. Trials focusing on non-clear RCC or those that treated clear cell tumors 
along with significant numbers of non-clear subtypes will be discussed. The 
role of cytoreductive nephrectomy and the use of neoadjuvant and adjuvant 
targeted therapy will be reviewed. Lastly, areas of future research will be 
highlighted.
Results: The majority of clinical trials testing novel targeted therapies 
have excluded non-clear subtypes, providing limited therapeutic options for 
patients with these diagnoses and their oncologists. 
Conclusion: Patients presenting with advanced non-clear pathology 
should undergo a thorough metastatic evaluation and, if appropriate, 
surgical evaluation to determine if nephrectomy, lymphadenectomy, and/
or metastectomy are warranted. Aggressive surgical extirpation is often 
recommended. Sunitinib also is adequately tolerated and oncologically active 
in subjects with non-clear histology.

Urol J. 2011;8:1-11. 
www.uj.unrc.ir

Keywords: kidney neoplasms, 
renal cell carcinoma, classification, 

mortality

1Department of Medical Oncology, 
National Institute of Oncology, 

Rabat, Morocco
2Department of Urology, Chu 

Hassan Ii, Fez, Morocco

Corresponding Author:
El Mehdi Tazi, MD

Tel: +21 266 847 9120
Fax: +21 253 767 2580

E-mail: moulay.elmehdi@yahoo.fr

Received November 2010
Accepted February 2011

INTRODUCTION

Background
Renal cell carcinoma (RCC) is 
among the most common adult 
malignancies in the United States, 
ranking fifth in men and eighth 
in women, with approximately 
57 760 new cases diagnosed in 
2009.(1) Renal cell carcinoma is not 
a homogenous entity and a number 
of malignant histologic subtypes, 
such as clear cell, papillary, 
chromophobe, and collecting duct, 

are recognized by the Heidelberg 
classification system (Figure).(2)
Each RCC subtype is associated 
with unique genetic alterations, 
clinical characteristics, and 
sensitivity to treatment.(3-5)

The systemic management of 
advanced and metastatic RCC 
has drastically altered over the 
past 5 years with the approval 
of a number of targeted agents, 
supplanting cytokine-based 
therapies as the treatment of 



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2 Urology Journal   Vol 8   No 1   Winter 2011

choice for the majority of patients with clear cell 
RCC.(6-8) Despite these advances, the optimal 
treatment for patients with non-clear histologies 
remains undefined. This review will discuss 
the genetic and molecular biology of papillary, 
chromophobe, and collecting duct RCC and the 
targeted therapeutic strategies being employed to 
treat them.

Clear cell RCC, which is the most common 
histologic subtype of RCC and accounts for 
approximately 75% of the kidney cancer 
diagnoses,(9) provides the paradigm for 
translational research that takes bench top 
basic science to bedside therapies. Mutations 
in the von Hippel-Lindau (VHL) gene, which 
is located on the short arm of chromosome 3 
and serves as an autosomal dominant tumor 
suppressor, were identified by studying 
patients afflicted with hereditary and sporadic 
clear cell kidney cancer.(4,10,11) Targeting the 
downstream transcriptional products resulting 
from mutational inactivation of the VHL gene, 
which are involved in angiogenesis and cellular 
proliferation and include vascular endothelial 
growth factor (VEGF), transforming growth 

factor  (TGF ), and platelet-derived growth 
factor  (PDGF ),(12) allowed novel agents, such 
as sunitinib,(11) sorafenib,(13) and temsirolimus,(14)
to be introduced against a disease that is 
notoriously resistant to cytotoxic chemotherapy 
and radiotherapy.(15) While these agents mark 
a major advance in the treatment of clear cell 
RCC, nearly every trial in which they were tested 
excluded the other subtypes of RCC, providing 
clinicians and their patients little guidance when 
selecting a systemic treatment for non-clear cell 
RCC. Fortunately, the same methodology of 
studying the genetic and molecular characteristics 
of hereditary and sporadic non-clear cell RCC 
tumors has identified promising new pathways 
that are amenable to targeted therapy.(5)

Objective
The primary aim of this review is to assess the 
development of targeted systemic therapies.

This review will focus on the use of targeted 
therapies against the non-clear histologic subtypes 
of renal cell carcinoma; papillary I and II, 
chromophobe, and collecting duct.

Histopathologically distinct non-clear renal epithelial neoplasms and their incidence.

Papillary type I
5%

Papillary type II
10%

Chromophobe
5%



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3Urology Journal   Vol 8   No 1   Winter 2011

MATERIALS AND METHODS

Search Strategy
On the basis of MEDLINE database searches, we 
assessed all aspects of “targeted therapies in non-
clear cell carcinoma” between February 2000 and 
December 2010. Seventy-two articles were found 
to detail future strategies to understund and treat 
non-clear cell carcinoma on the basis of evolution 
in targeted therapies.

RESULTS

Papillary Renal Cell Carcinoma
Papillary RCC is the second most common 
histologic subtype of the kidney cancer, 
accounting for approximately 10% to 15% of 
cases and nearly 29% of all RCCs in African 
Americans.(9,16) It can be further categorized 
histologically into papillary types I and II. 
Emerging data suggests that there may be 
significant differences in the genetics and 
molecular pathways underlying different types 
of papillary RCC as well as disparate outcomes 
associated with these entities.(17) Researchers and 
clinicians must take these differences into account 
when they design targeted therapies and treatment 
protocols for patients with papillary RCC.

Papillary type I RCC, in both the sporadic and 
hereditary forms, is associated with activating 
mutations of the methyl-nitroso-nitroguanidine-
induced (MET) oncogene on the long arm of 
chromosome 7.(18) These mutations result in 
ligand-independent activation of intracytoplasmic 
tyrosine kinase domains, which constitutively 
activate the hepatocyte growth factor/MET 
pathway.(19,20) Families with hereditary papillary 
renal cancer harbor germline mutations in 
MET, usually accompanied by non-random 
duplication of the chromosome 7 bearing the 
mutated MET allele. Mutated MET is passed to 
offspring in an autosomal dominant fashion with 
variable penetrance. Phenotypically, patients 
with this gain of function germline mutation 
display bilateral multifocal papillary type I renal 
tumors.(20) Activated somatic MET mutations 
have also been identified in the tumors of patients 
with sporadic papillary type I RCC. While one 

study identified mutations in 13% of patients with 
all subtypes of non-familial papillary RCC, the 
prevalence of this genetic alteration in sporadic 
type I papillary RCC has not been adequately 
defined.(21)

Papillary type II tumors are now recognized 
as a distinct entity and occur both sporadically 
and in patients who have the familial syndrome 
of hereditary leiomyomatosis and renal cell 
carcinoma (HLRCC).(22) The genetic alteration 
associated with HLRCC has been localized 
to chromosome 1 and the gene identified as 
fumarate hydratase (FH). Fumarate hydratase 
functions as a classic tumor suppressor, with both 
copies inactivated in tumors. The mutation is 
transmitted in an autosomal dominant pattern 
with high penetrance.(23) Patients with HLRCC 
are at risk for the development of papillary 
RCC. These tumors have characteristic large 
orangeophilic nuclei and a clear perinuclear halo, 
with a variety of architectural patterns, such as 
papillary, tubulo-papillary, tubular, solid, or 
mixed.(24) Fumarate hydratase is a tricarboxylic 
acid (Krebs) cycle enzyme that plays a crucial 
role in aerobic cellular metabolism.(25) One 
well-described consequence of FH inactivation 
is the generation of a pseudo-hypoxic state, 
characterized by the upregulation of hypoxia-
inducible factors (HIF), similar to that seen in the 
VHL pathway, albeit by a different mechanism.

Isaacs and colleagues demonstrated that 
inactivation of FH and consequent accumulation 
of its substrate, fumarate, lead to inhibition 
of HIF prolyl hydroxylase (HPH), a critical 
enzymatic regulator of intracellular HIF levels, 
through competitive inhibition.(25) Inactivation of 
HPH interferes with hydroxylation of HIF at key 
proline residues and its subsequent recognition 
by the VHL complex; thus, preventing VHL-
dependent proteosomal degradation of HIFs. 
The resulting accumulation of HIF leads to 
transcriptional overexpression of proangiogenic 
factors, such as VEGF, as well as other genes, 
such as TGF- , PDGF, and glucose transport 
(GLUT-1). In essence, this is an example of 
VHL-independent HIF accumulation in fumarate 
hydratase deficient kidney cancer, resulting in 
increased amounts of proangiogenic and growth 



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4 Urology Journal   Vol 8   No 1   Winter 2011

factors.(25) There is currently no well-described 
sporadic counterpart to HLRCC-associated 
kidney cancer and no conclusive evidence that 
somatic FH mutations play a significant role in 
sporadic kidney cancer tumorigenesis. However, 
the role of mutations in FH and other Krebs 
cycle enzymes, such as succinate dehydrogenase 
in the genesis of sporadic papillary RCC, is under 
evaluation.

Localized papillary RCC, which can be managed 
with surgical excision, has a more favorable 
prognosis than conventional clear cell.(26,27)
However, metastatic papillary RCC portends 
a worse prognosis.(28) Few trials have focused 
their attention on papillary RCC as the primary 
histologic tumor type; therefore, the majority 
of data available is from expanded access trials, 
retrospective studies, and subset analyses with the 
inherent limitations these methods imply. 

The Advanced Renal Cell Carcinoma Sorafenib 
Expanded Access Program allowed patients in 
the United States and Canada with metastatic 
RCC to receive treatment with sorafenib prior 
to its regulatory approval. This non-randomized, 
open-label program treated 158 subjects with 
papillary RCC of a total of 1891 evaluable 
subjects (81% clear cell, 8% non-clear, and 11% 
unclassified histology).(29) Of the 107 evaluable 
subjects with papillary RCC, 90 (84%) had a 
measurable response to treatment with 3 partial 
responders and 87 with stable disease for at least 
8 weeks, while 17 (16%) subjects demonstrated 
early progression on treatment. The side effect 
profile for sorafenib was similar across histologic 
subtypes, and the authors concluded that 
sorafenib has some activity in papillary tumors. 

Gore and associates treated 588 subjects with 
non-clear histology (not further subclassified) in 
their multi-center, international, non-randomized, 
expanded access compassionate use trial 
examining the safety and efficacy of sunitinib.(30)
Of these, 437 were evaluable; however, the trial 
did not predefine criteria for measuring response, 
which was instead determined according to 
local practice. A total of 48 (11%) subjects had 
an objective response (46 partial responses and 
2 complete responses), while 250 (57%) had 
stable disease for 3 months. Nearly one-third of 

the subjects (n = 139; 32%) progressed within 
3 months. Despite focusing on poor-prognosis 
populations that were typically excluded from 
other trials because of the presence of brain 
metastases, Eastern Cooperative Oncology 

profile of sunitinib was similar to that seen in 
traditional patient populations.(11,31-33) The median 
overall survival (OS) for subjects with non-clear 
RCC in this study was 13.4 months, which is an 
improvement over the historical control of 9.4 
months (a historical control was used given the 
non-randomized design of this trial).(34) The lower 
overall response rate (11%) for the non-clear 
histology group may have been influenced by the 
lack of a protocol-mandated evaluation procedure 
and the dependence on local standards of care to 
measure changes in disease burden.(30) Despite this 
limitation, the authors concluded that sunitinib 
is adequately tolerated and oncologically active 
in poor-prognosis populations, including subjects 
with non-clear histology, and that its use and 
further study are appropriate.

Choueiri and coworkers reported their 
retrospective multi-center review of 41 subjects 
with metastatic papillary RCC, who were 
treated with either sunitinib or sorafenib in the 
United States and France, which represents one 
of the largest papillary-only series published to 
date.(35) They found that although response rates 
were low (5% overall, 17% for sunitinib group), 
progression-free survival (PFS) was longer in those 
treated with sunitinib rather than sorafenib (11.9 
months versus 5.1 months; P < .001). While the 
number of subjects in this retrospective analysis 
was small and the overall response rate was low, 
the PFS in patients treated with sunitinib is 
similar to that published for subjects with clear 
cell histology,(12) suggesting some activity for this 
agent. Unfortunately, there was no stratification 
of subjects based on papillary I versus II subtypes, 
which may indicate that the natural history and 
aggressiveness of these two entities were not 
adequately controlled in this trial.

In contrast, a recent report from Plimack and 
colleagues of their phase II experience with 
sunitinib in 23 patients with advanced papillary 



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5Urology Journal   Vol 8   No 1   Winter 2011

RCC outlines the minimal activity associated 
with this drug and underscores the need to 
look beyond single agent VEGF pathway 
antagonists.(36) No objective responses were 
seen in this prospective, single-arm study. Eight 
patients had stable disease as their best response 
with a median PFS of only 1.6 months and 
median OS of 10.6 months. Similarly, Ravaud and 
associates from the French Genito-Urinary Group 
and the Group of Early Phase Trials examined 
sunitinib as a first-line therapy in subjects with 
locally advanced or metastatic papillary RCC in 
their on-going phase II trial. Their preliminary 
data on 5 subjects with papillary I and 23 subjects 
with papillary II RCC found no papillary 
I responders and only 1 papillary II partial 
response.(37)

Hudes and coworkers also included a significant 
number of subjects with non-clear histology in 
their Global Advanced RCC Trial comparing 
temsirolimus, interferon alfa, or both for 
advanced RCC.(14) This international, multi-
center, randomized phase III trial treated a total of 
626 subjects with poor-prognosis metastatic RCC. 
One hundred and twenty-four (20%) subjects 
were classified as having non-clear cell RCC. 
However, a central pathology review was not 
performed and further subclassification was not 
provided. Subjects of all histologic types receiving 
temsirolimus monotherapy had a median OS of 
10.9 months, compared to 7.3 and 8.4 months 
for the groups receiving interferon alfa alone 
or temsirolimus plus interferon, respectively. 
Likewise, median PFS times were 5.5, 3.1, 
and 4.7 months, respectively, using Response 
Evaluation Criteria in Solid Tumor (RECIST) 
completed by independent radiologists. Hazard 
ratios for OS among the non-clear RCC subgroup 
also favored treatment with temsirolimus over 
interferon alfa. Subsequent exploratory subset 
analyses based on tumor histology from Global 
Advanced RCC determined that 55 subjects had 
papillary RCC and that those in the temsirolimus 
group (n = 25) had prolonged OS (11.6 versus 
4.3 months, respectively) and PFS (7.0 versus 1.8 
months, respectively) compared to those treated 
with interferon alfa (n = 30).(38) Although these 
data represent an exploratory subset analysis, 
this report is significant in that temsirolimus is 

the only agent approved by the Food and Drug 
Administration for advanced RCC that has been 
evaluated in non-clear cell RCC in a phase III 
trial. These data suggest that mammalian target 
of rapamycin (mTOR) inhibitors, either as single 
agents or in combination, should be further 
evaluated in papillary RCC in prospective studies.

A prospective phase II trial of everolimus, an oral 
mTOR inhibitor, as monotherapy in advanced 
papillary RCC, is ongoing in Europe. Foretinib 
(also known as GSK1363089 or XL880) is an oral 
receptor tyrosine kinase inhibitor (TKI) that 
targets c-MET and VEGFR2 and has been studied 
in a phase II multi-center trial.(39) Two different 
dosing regimens, a daily and an intermittent 
dosing regimen, were evaluated in this trial. 
Interim data on the first 60 patients (37 in the 
intermittent dosing arm and 23 in the daily dosing 
cohort) were reported recently in abstract form. 
Response Evaluation Criteria in Solid Tumor 
partial responses were seen in 7/53 evaluable 
patients, including 4/37 or 11% of patients 
receiving intermittent dosing and 3/16 or 19% of 
patients on the daily dosing regimen. In addition, 
over 70% of patients treated had stable disease, 
with the majority demonstrating some degree of 
tumor shrinkage. The drug was well-tolerated, 
with a side effect profile akin to that seen with 
other VEGF receptor antagonists. The trial has 
completed accrual and final efficacy analysis is 
awaited. Foretinib is the first MET antagonist 
to be evaluated in papillary RCC and patients 
will be retrospectively stratified based on c-MET 
status to determine if clinical efficacy is correlated 
with MET activation.

Erlotinib is an oral epidermal growth factor 
receptor tyrosine kinase inhibitor. A multi-
center phase II trial of this agent in patients 
with locally advanced and metastatic papillary 
RCC reported an overall RECIST response 
rate of 11% (5/45 patients) with an additional 
24 (53%) patients experiencing stable disease.(40)
The 6-month PFS was only 29%; however, 
the median OS was 27 months. Although this 
was a single-arm, uncontrolled study, the OS 
reported was higher than that has been reported 
for patients with metastatic papillary RCC.(34,35)
Addition of mTOR inhibitors or VEGF pathway 



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6 Urology Journal   Vol 8   No 1   Winter 2011

antagonists may potentiate the single agent 
activity of erlotinib. A phase II trial of erlotinib 
in combination with bevacizumab is currently 
underway and is one of the trials designed to 
evaluate this strategy.(41)

Chromophobe Renal Cell Carcinoma
Chromophobe RCC accounts for approximately 
4% of all RCCs(9) and is often detected while 
still confined to the kidney, as less than 5% of 
cases are metastatic at the time of diagnosis.(26,27)
The mechanisms underlying the genesis of 
this subtype of RCC are not well-understood. 
However, studies focusing on a familial form 
of chromophobe kidney cancer are beginning 
to provide some early insights that might help 
elucidate the molecular pathways driving this 
malignancy.

Birt-Hogg-Dubé (BHD) is an autosomal 
dominant hereditary cancer syndrome associated 
with bilateral, multifocal chromophobe RCC. 
Approximately, one-third of patients with 
BHD have this renal manifestation, with 5% 
demonstrating oncocytomas, and an additional 
50% demonstrating hybrid chromophobe/
oncocytic tumors.(42,43) The BHD gene, FLCN, 
located on the short arm of chromosome 17, 
was identified by genetic linkage analysis,(38,44)
and is altered via insertion, deletion, or nonsense 
mutations in the germline of the vast majority 
of affected individuals.(45) The protein product 
of BHD, folliculin, functions as a tumor 
suppressor.(46) The function of folliculin and 
the consequences of folliculin loss in BHD are 
currently under study. Available data indicate that 
folliculin is a component of the cellular energy 
sensing system and may interact with cellular 
activated mitogen protein kinase (cAMPK) and 
mTOR pathways. Investigators at the National 
Cancer Institute have demonstrated mTOR 
upregulation in FLCN-/- tumors, with activation 
of both mTORC1 and mTORC2 pathways.(47)
Additionally, the mTOR inhibitor rapamycin 
appears to ameliorate the renal phenotype and 
prolong survival in conditional FLCN-/- mice. 
These data suggest a role for mTOR inhibitors in 
the management of BHD-associated tumors. The 
relevance of the BHD and mTOR pathways in 

sporadic chromophobe RCC is an area of active 
investigation. It is hoped that these studies will 
help identify rational targets and help determine 
the utility of mTOR inhibitors in this patient 
population.

Upregulation of cellular proto-oncogenic 
receptor tyrosine kinase (c-KIT) has also been 
associated with chromophobe RCC;(48) however, 
its precise role in the genesis and progression of 
these tumors is unclear. C-KIT is a target that 
is amenable to pharmacologic inhibition, and 
several agents currently available, including 
imatinib, sunitinib, and sorafenib, have been 
shown to inhibit this molecule. Like papillary 
RCC, chromophobe tumors have been excluded 
from many of the initial targeted therapy trials. 
The available data are even more limited given 
that chromophobe RCC is less common and less 
likely to metastasize than papillary RCC, making 
attempts at subset analyses tenuous. Stadler and 
colleagues treated 20 subjects with chromophobe 
RCC as part of the Advanced RCC Sorafenib 
Expanded Access Program.(29) They saw an 
overall disease control rate of 90%, with 1 (5%) 
partial response and 17 (85%) subjects with stable 
disease for at least 8 weeks, while 2 (10%) subjects 
had disease progression. Chromophobe tumors 
were also included in the temsirolimus versus 
interferon alfa trial, but the published subgroup 
analysis by tumor histology only examined 
papillary tumors.(49) However, the OS and PFS 
were prolonged in the aggregate non-clear group 
treated with temsirolimus, providing evidence, 
albeit weak, for the use of temsirolimus over 
interferon alfa in advanced chromophobe RCC.

Collecting Duct Renal Cell Carcinoma
Collecting duct RCC is extremely rare, 
accounting for less than 1% of all RCCs(9)
and is associated with a grave prognosis, with 
approximately one-third of patients having 
metastases at the time of diagnosis.(34) This 
malignancy is thought to arise from the collecting 
ducts of the renal medulla. Medullary carcinoma 
is an especially virulent type of the collecting duct 
RCC that is associated with sickle cell trait and is 
often seen in young African American patients.

Due to the rarity of this disease, there is scant 



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7Urology Journal   Vol 8   No 1   Winter 2011

evidence to guide treatment recommendations, 
and no randomized clinical trials have been 
completed.(50) The strongest treatment evidence 
available comes from a phase II multi-center 
trial of 23 treatment-naive metastatic subjects 
who were given gemcitabine plus cisplatin or 
carboplatin, depending on renal function.(51)  This 
regimen was selected based on the histologic 
similarities between the collecting duct RCC and 
transitional cell carcinoma of the urinary bladder. 
Oudard and associates found that 26% of subjects 
had a response to treatment per RECIST criteria 
(5 partial responses and 1 complete response) as 
measured by independent radiologic review; PFS 
was 7.1 months with an OS of 10.5 months.(51)

There is not enough data to comment on the role 
of TKIs or mTOR inhibitors in this type of RCC. 
Clearly more therapeutic options are needed for 
this disease. 

Cytoreductive Nephrectomy, Neoadjuvant, 
and Adjuvant Therapy
Cytoreductive nephrectomy (CN) followed 
by systemic interferon was shown in two 
randomized trials to provide a statistically 
significant, albeit limited, improvement in 
survival (13.6 months for CN plus interferon 
versus 7.8 months for interferon alone when these 
two trials were analyzed in combination).(52-54)
Based on these data, CN was adopted as the 
standard of care in the cytokine era. With the 
emergence of targeted therapies, the role of CN 
has not yet been directly re-evaluated with a 
randomized prospective study; however, the 
majority of subjects in the three major trials 
of sunitinib, sorafenib, and temsirolimus had 
undergone nephrectomy prior to receiving 
systemic therapy.(11-13)

The exact mechanism by which CN confers a 
survival advantage is still being elucidated, but 
potential explanations include removing bulky 
primary tumors which act as immunologic sinks 
for antibodies and tumor reactive lymphocytes, 
delaying disease progression, decreasing disease 
burden,(55) and reducing the amount of growth 
factors secreted by the primary tumor.(56) While 
most of these hypotheses were invoked to explain 
the utility of CN followed by cytokine therapy, 

some of these mechanisms may also be relevant 
in the era of targeted therapies designed to disrupt 
the proangiogenic pathways that are activated in 
RCC.

Prospective data on the use of CN in combination 
with targeted therapies in the metastatic clear 
cell RCC population are limited and this 
approach warrants further study. Phase III 
studies of sunitinib alone versus sunitinib with 
CN (CARMENA) and pre-surgical versus post-
surgical sunitinib (EORTC) are currently ongoing 
in Europe.(57) In non-clear histologies, data from 
studies examining the role of CN are limited 
and largely based on retrospective subgroup 
analyses.(28,34,58)

Recently, Kutikov and colleagues published their 
series of 141 subjects, 98 of whom underwent 
CN and received systemic immunotherapy or 
targeted therapy between 1990 and 2008.(59) Of 
132 subjects with an identifiable RCC histology, 
7 (5.3%) had papillary and 2 (1.5%) had collecting 
duct RCC. Of these 9 subjects, 8 were able to 
receive systemic therapy following CN while 1 
subject with the collecting duct RCC had rapid 
disease progression precluding systemic therapy. 
Across all histologies, rapid disease progression 
was the reason why 13 of 43 subjects (30%) could 
not receive systemic therapy after CN. The 
authors found that only poor baseline ECOG 
performance status predicted which subjects 
would not be able to receive post-CN systemic 
treatment, a conclusion that echoes those of prior 
studies.(60)

Some authors consider non-clear histology to be 
a relative contraindication to CN given the scant 
data available to support a survival advantage, the 
known morbidity, and possible mortality that 
is associated with the procedure.(57) However, 
given the limited systemic options available, 
aggressive surgical resection in appropriately 
selected candidates seems to offer the patient with 
advanced or metastatic non-clear RCC the best 
chance for prolonged survival currently available. 
Additional trials are needed to address how to 
identify the optimal candidate for CN, which 
systemic targeted therapy agent or agents to use, 
and in what order to employ them.



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8 Urology Journal   Vol 8   No 1   Winter 2011

Neoadjuvant systemic therapy has been shown 
to benefit patients with advanced bladder, 
metastatic germ cell, and metastatic colon cancer. 
No trials directly address the use of neoadjuvant 
systemic targeted therapy for non-clear RCC, 
but several case series have been published 
and several centers, such as M.D. Anderson 
Cancer Center, University of North Carolina 
at Chapel Hill, and the Cleveland Clinic have 
active protocols addressing this issue; however, 
none are exclusively focused on non-clear 
histologies.(61) The goals of neoadjuvant therapy 
are to downstage the primary tumor in order to 
make extirpative surgery feasible or technically 
less challenging and to eradicate micrometastatic 
disease, as distant failure portends a poor 
prognosis.(55,62) A significant portion of patients 
undergoing aggressive surgical resection fails to 
receive systemic therapy because of rapid disease 
progression.One treatment strategy described by 
Margulis and Wood at M.D. Anderson Cancer 
Center is to treat surgically unresectable patients 
with sunitinib for four weeks followed by 
restaging.(63) Patients with a favorable response 
can proceed to extirpative surgery while those 
who fail to respond or progress are treated with a 
different systemic agent. The goal of this schema 
is to identify those patients who are likely to 
progress rapidly and therefore never receive 
adjuvant therapy after CN, and treat them 
systemically while avoiding the morbidity of 
major surgery. This is an intriguing study design 
and should be replicated in the setting of non-
clear histology, particularly once active systemic 
agents become available.

The use of cytokine therapy in the adjuvant 
setting to reduce the risk of distant failure 
following local treatment with curative intent 
was not found to be beneficial in patients with 
clear cell RCC.(64-66) Adjuvant targeted therapies 
are now being evaluated with trials in the United 
States, Europe, and Asia.(8) For example, the 
Eastern Cooperative Group sponsored ASSURE 
(Adjuvant Sorafenib or Sunitinib for Unfavorable 
Renal Carcinoma) trial is open to all histologies 
except collecting duct or medullary carcinoma; 
enrollment is ongoing, but no results have 
been reported. Southwest Oncology Group’s 
EVEREST (Everolimus in Treating Patients with 

Kidney Cancer who have Undergone Surgery) is 
open to all histologies except the collecting duct 
or medullary RCC and compares everolimus 
to placebo in the adjuvant setting. Similarly, 
the industry-sponsored S-TRAC (Sunitinib 
Treatment of Renal Adjuvant Cancer) is also open 
to all RCC subtypes except the collecting duct 
and is accruing subjects. The United Kingdom’s 
Medical Research Council-sponsored SORCE 
(Sorafenib in Treating Patients at Risk of Relapse 
after Undergoing Surgery to Remove Kidney 
Cancer) is open to all histologies, but as expected 
in an adjuvant trial, nephrectomy is the only 
prior RCC treatment allowed.

FUTURE RESEARCH
Despite recent advances, there remains a paucity 
of effective systemic options directly applicable 
to advanced and metastatic non-clear cell RCC. 
Histology-specific and mechanism-based studies 
addressing virtually all aspects of papillary, 
chromophobe, and the collecting duct RCC are 
essential for continued progress in our attempts to 
determine optimal management of these patients.

The identification of several familial forms of 
renal cancer has greatly enhanced our ability to 
study and understand the genetic alterations and 
biochemical pathways unique to distinct subtypes 
of RCC. As with clear cell RCC, better molecular 
characterization will likely enable development 
of rational targeted strategies against other 
subtypes of familial kidney cancer as well as their 
sporadic counterparts. Due to the rarity of these 
conditions, multi-center cooperative trials have 
the highest likelihood of accruing enough subjects 
to adequately power prospective studies.

Several agents currently available demonstrate 
modest activity in patients with non-clear cell 
RCC. Trials investigating combinations of one 
or more of these agents, either administered 
in sequence or given concomitantly, may 
improve outcomes compared to monotherapy 
by allowing targeting of multiple pathways of 
tumorigenesis simultaneously. Neoadjuvant 
targeted therapy with or without CN is likely to 
become increasingly relevant in the management 
of selected patients with advanced clear cell 
RCC. Its role in the non-clear patient population 



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9Urology Journal   Vol 8   No 1   Winter 2011

must be elucidated further. Risk factors other 
than performance status must be identified to 
properly stratify patients given the morbidity 
of CN and the high percentage of patients 
who rapidly progress despite systemic therapy. 
Histology-specific circulating tumor markers are
quite promising in this regard(61,67) and may help 
identify who should receive systemic treatment 
immediately instead of CN, as well as serve 
as non-radiographic (non-RECIST) surrogates 
or predictors of tumor response.(8) Similarly, 
the optimal duration of and timing between 
neoadjuvant treatment and CN need further 
definition; however, reports have not described 
significant problems with wound healing or other 
increased morbidity thus far.(62,63,68)

The impact of targeted therapies on patient’s 
quality of life must also be examined along 
with the more traditional oncologic endpoints 
of adverse events, disease progression, and 
survival.(69) Targeted therapies offer tremendous 
therapeutic opportunities to patients, but also 
come with unique and often unavoidable side 
effects.(70) A number of validated, cancer-specific, 
and kidney cancer-specific instruments exist, but 
there are neither histology-specific nor widely 
accepted standard quality of life surveys for RCC 
at this time.(71) Quality of life endpoints should 
be included in all prospective targeted therapy 
studies and considered as an essential component 
for multi-center and cooperative group trials 
in order to ensure that the goal of alleviating 
suffering is advanced along with the goals of 
prolonging survival and identifying cures for 
patients with non-clear RCC.

CONCLUSION
Targeted therapies have greatly expanded the 
treatment options available to patients with 
advanced and metastatic non-clear cell RCC. 
However, much work is needed in order to 
determine the optimal agent(s) against each 
histologic subtype.

Patients presenting with advanced non-clear 
pathology should undergo a thorough metastatic 
evaluation and, if appropriate, surgical evaluation 
to determine if nephrectomy, lymphadenectomy, 
and/or metastectomy are warranted.

Aggressive surgical extirpation is often 
recommended at the National Cancer Institute 
given the poor survival associated with these 
entities and the limited evidence available to drive 
the selection of systemic therapy.

All patients should be encouraged to consider 
participating in clinical trials and referred to 
appropriate medical centers. At the present time, 
the literature offers limited support for the use 
of VEGF and mTOR inhibitors to treat patients 
with advanced or metastatic non-clear cell RCC. 
The results of prospective trials examining 
treatments for papillary, chromophobe, and the 
collecting duct RCC are eagerly awaited.

CONFLICT OF INTEREST
None declared.

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