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	arXiv:1001.0009v1 [q-bio.BM] 30 Dec 2009Jamming proteins with slipknots and their free energy lands cape
	Joanna I. Su/suppress lkowska1, Piotr Su/suppress lkowski2,3,4and Jos´ e N. Onuchic1
	1Center for Theoretical Biological Physics,
	University of California San Diego,
	Gilman Drive 9500, La Jolla 92037,
	2Physikalisches Institute and Bethe Center for Theoretical Physics,
	Universit¨ at Bonn, Nussallee 12, 53115 Bonn, Germany
	3California Institute of Technology, Pasadena, CA 92215,
	4Institute for Nuclear Studies,
	Ho˙ za 69, 00-681 Warsaw, Poland
	Theoretical studies of stretching proteins with slipknots reveal a surprising growth of their un-
	folding times when the stretching force crosses an intermed iate threshold. This behavior arises as
	a consequence of the existence of alternative unfolding rou tes that are dominant at diﬀerent force
	ranges. Responsible for longer unfolding times at higher fo rces is the existence of an intermediate,
	metastable conﬁguration where the slipknot is jammed. Simu lations are performed with a coarsed
	grained model with further quantiﬁcation using a reﬁned des cription of the geometry of the slip-
	knots. The simulation data is used to determine the free ener gy landscape (FEL) of the protein,
	which supports recent analytical predictions.
	PACS numbers: 87.15.ap, 87.14.E-, 87.15.La, 82.37.Gk, 87. 10.+e
	The large increase in determining new protein struc-
	tures has led to the discovery of several proteins with
	complicated topology. This new fact has arised the ques-
	tion if their energy landscape and the folding mechanism
	is similar to typical proteins. One class of such proteins
	includes knotted proteins which comprise around 1% of
	all structures deposited in the PDB database [1, 2]. A
	related class of proteins contains more subtle geometric
	conﬁgurations called slipknots [3, 4]. Recent theoretical
	studies using structure-based models (where native con-
	tacts are dominant) suggest that slipknot-like conforma-
	tions act like intermediates during the folding of knotted
	proteins [5]. This entire new mechanism is consistent
	with energy landscape theory (FEL) and the funnel con-
	cept [7, 8]. It was shown that the slipknot formation
	reduces the topological barrier. Complementing regular
	folding studies, additional information about the land-
	scape was obtained by mechanical manipulation of the
	knotted protein with atomic force microscopy [9] both
	experimentally in [10, 11] and theoretically in [12, 13, 14].
	For example, [12] it has been showen that unfolding pro-
	ceeds via a series of jumps between various metastable
	conformations, a mechanism opposite to the smooth un-
	folding in knotted homopolymers.
	Motivated by these early results, we now propose a uni-
	ﬁed picture for the mechanical unfolding of proteins with
	slipknots. In this Letter this question is addressed by
	explaining the role of topological barriers along their me-
	chanical unfolding pathways. Supported by our previous
	results that knotted proteins can still have a minimally
	frustrated funnel-like energy landscape, structure-based
	theoretical coarse-grained models are used [15] to ana-
	lyze the behavior of a slipknot protein under stretching.
	Studies are performed for the α/β class protein thymi-dine kinase (PDB code: 1e2i [17]).
	2 3 4 5F/LBracket1Ε/Slash1/Angstrom/RBracket17.27.57.88.1logΤ
	FIG. 1: Dependence of the unfolding times τon the stretch-
	ing force Ffor 1e2i (solid line, in red). In this Letter we
	describe this mechanism as a superposition of two unfolding
	pathways: I for small forces (dashed (lower) line, in blue),
	and II for intermidiate and large forces (dashed-dotted (up -
	per) line, green).
	Most of our analysis is based on stretching simulations
	under constant force [16]. The crucial signature for this
	process is the overall unfolding time from the beginning
	of the stretching until the protein fully unfolds. Normally
	one expects that the transition between the native and
	the unfolded basins to be limited by overcoming the free
	energy barrier, which gets eﬀectively reduced upon an
	application of a stretching force. The rate by which this
	barrier is reduced depends on the distance between the
	unfolded basin and the top of the barrier measured along
	the stretching coordinate x. This idea was ﬁrst devel-
	oped in the phenomenological model of Bell [18], which
	states that the unfolding time τdecreases exponentially
	with applied stretching force Fasτ(F) =τ0e−Fx
	kBT. A2
	reﬁned analysis performed in ref. [19] revealed that this
	dependence is more complicated but still monotonically
	decreasing.
	The unfolding times for 1e2i measured in our simula-
	tions are shown as the red curve in Fig. 1. In contrast to
	the above expectations, increasing the force in the range
	3-3.5ǫ/˚A surprisingly results in a larger stability of the
	protein. ǫis the typical eﬀective energy of tertiary na-
	tive contacts that is consistent with the value ǫ/˚A≃71
	pN derived in [15]. A solution for this paradox is accom-
	plished by realizing that unfolding is dominated by two
	distinct, alternative routes that are dominant at diﬀerent
	force regimes. A routing switch occurs when threshold is
	crossed between weak and intermediate forces. At higher
	forces, mechanical unfolding is dominated by a route that
	involves a jammed slipknot. This jamming gives rise to
	the unexpected dependence of unfolding time on applied
	force. Characterizing this mechanism is the central goal
	of this Letter.
	FIG. 2: A slipknot (left) consists of a threaded loop (k1−k2,
	in red) which is partialy threaded through a knotting loop
	(k2−k3, in blue). An example of a protein conﬁguration with
	a tightened slipknot is shown in the right panel.
	To describe the evolution of a slipknot quantitatively
	requires a reﬁned description. A slipknot is character-
	ized by the three points shown in Fig. 2. The ﬁrst
	pointk1is determined by eliminating amino acids con-
	secutively from one terminus until the knot conﬁgura-
	tion is reached (which can be detected e.g. by applying
	the KMT algorithm [20]). The two additional points,
	k2andk3, correspond to the ends of this knot. In the
	native state the protein 1e2i contains a slipknot with
	k1= 10,k2= 128,k3= 298. These three points divide
	the slipknot into two loops, which are called the knotting
	loop and thethreaded loop . The former one is the loop of
	the trefoil knot and the latter one is threaded through the
	knotting loop. Unfolding of the slipknot upon stretch-
	ing depends on the relative shrinking velocity of these
	two loops (see Fig. 3). When the threaded loop shrinks
	faster than the knotting loop, the slipknot unties. In the
	opposite case the slipknot gets (temporarily) tightened
	or jammed, resulting in a metastable state associated
	to a local minimum in the protein’s FEL. Upon further
	stretching, this conﬁguration eventually also unties. The
	evolution of both loops of the slipknot is encoded in thetime dependence of the points k1,k2,k3, see Fig. 3.
	pathway I pathway II
	catch−bonds slip−bondspathway II
	catch−bonds slip−bondspathway I
	FIG. 3: The behavior of the slipknot during stretching (top)
	is determined by the relative behavior of its two loops, en-
	coded in the time dependence of k1,k2andk3(bottom). If the
	threaded loop shrinks faster than the knotting loop, k1merges
	withk2(bottom left) and the slipknot untightens (pathway I,
	top left). If the knotting loop shrinks faster, k2approaches k3
	(bottom right, ≃14000τ) and the slipknot gets temporarily
	tightened (pathway II, top right). This is a metastable stat e
	which can eventually untie further stretching , with k1ﬁnally
	merging with k2(bottom right, ≃19000τ). Kinetic stud-
	ies were performed slightly above folding temperature usin g
	overdamped Langevin dynamics with typical folding times of
	10000τ.
	Before discussing the stretching of 1e2i, we explain why
	a slipknot formed by a uniformly elastic polymer should
	smoothly unfold under stretching. To simplify the discus-
	sion we approximate the threaded and knotting loops by
	circles of size RtandRk. These two loops shrink during
	stretching and, when the threaded one eventually van-
	ishes, the slipknot gets untied. If both loops have similar
	sizes, the slipknot is very unstable and unties immedi-
	ately. When the threaded loop is much larger than the
	knotting one, Rt>> R k, untightening can be explained
	as follows. The elastic energy associated to local bend-
	ing is proportional to the square of the curvature. If the
	loop is approximated by a circle of radius R, then its local
	curvature is constant and equals R−1. The total elastic
	energy is/contintegraltext
	dsR−2∼R−1[21]. From the assumption
	Rt>> R kwe conclude that upon stretching it is ener-
	getically favorable to decrease Rtrather than Rk. This
	happens until both radii become equal and then, just as
	above, the slipknot gets very unstable and untightens. In
	this discussion we have not yet taken into account that
	when a slipknot is stretched some parts of a chain slide
	along each other. This eﬀect could be incorporated by in-
	cluding the friction generated by the sliding [22]. But in
	the slipknot the sliding region associated with the knot-
	ting loop is much longer than the region associated to3
	the threaded loop. Thus this eﬀect results in a faster
	tightening of the threaded rather than the knotting loop,
	facilitating even more the untightening of the slipknot.
	The above argument should apply to slipknots in
	biomolecules because they are characterized by a per-
	sistence length that in principle is simply related to their
	elasticity [23]. For DNA this eﬀect is described by worm-
	like-chain models (WLC) [24] and it has been conﬁrmed
	experimentally. Although WLC models are too simple
	to describe the protein general behavior, they are use-
	ful in some limited applications. Thus at ﬁrst sight one
	might expect that slipknots in proteins should smoothly
	untie upon stretching. Proteins, however, are much more
	complicated than DNA or uniformly elastic polymers.
	The presence of stabilizing native tertiary contacts leads
	to a jumping character during stretching [12]. In addi-
	tion their bending energy is not uniform along the chain
	due to the heterogeneity of the amino-acid sequence. As
	a consequence it turns out that the intuition obtained
	through the above analysis of polymers or WLC models
	is misleading.
	2 3 4 5F/LBracket1Ε/Slash1/Angstrom/RBracket10.51Prob/LParen1pathway I/RParen1
	FIG. 4: Dependence on the applied stretching force of the
	probability of choosing pathway I rather than II (see Fig. 3) .
	This varying probability leads to the complicated dependen ce
	of the total unfolding time on the stretching force observed in
	Fig. 1.
	Our analysis of the evolution of the endpoints k1,k2,k3
	(Fig. 3, bottom) reveals that for various stretching forces
	unfolding proceeds along two distinct pathways (Fig. 3,
	top). In pathway I the slipknot smoothly unties, which
	is observed for relatively weak forces. At intermediate
	forces pathway II starts to dominate and the knotting
	loop can shrink tightly before the threaded one vanishes.
	In this regime the protein gets temporarily jammed (Fig.
	3, right), leading to much longer unfolding times (catch
	pathway). The probability of choosing pathway I at dif-
	ferent forces is shown in Fig. 4. This pathway competi-
	tion explains the nontrivial total unfolding time depen-
	dence observed in Fig. 1.
	The two diﬀerent pathways I and II arise from com-
	pletely diﬀerent unfolding mechanisms. Pathway I starts
	and continues mostly from the C-terminal side, along
	16α, 15β, 14α, 13β, 12(helices bundle), 11 α(here the
	number denotes a consecutive secondary structure ascounted from N-terminal, and αorβspeciﬁes whether
	this is a helix or a β-sheet; for more details about the
	structure of 1e2i see the PDB). This is followed by unfold-
	ing of helices 11 α, 10αthat allows breaking of the con-
	tacts inside the β-sheet created by the N-terminal, with
	unfolding proceeding also from the N-terminal. Pathway
	II also starts from the C-terminal but rapidly (as soon
	as helix 15 is unfolded) switches to the N-terminal. In
	this case, diﬀerently from pathway I, the β-sheet from
	the N-terminal unfolds even before 13 β. These scenarios
	indicate that the pathway I should be dominant at weak
	forces since they are not suﬃcient to break the β-sheet
	during ﬁrst steps of unfolding. The jammed pathway is
	typical only if stretching forces are suﬃciently strong for
	unfolding to proceed from the two terminals of the pro-
	tein.
	A similar phenomenon was ﬁrstly proposed in ref. [25]
	and referred to as catch-bonds. Experimental evidence
	suggesting this mechanism was ﬁrst observed for adhe-
	sion complexes [26, 27]. Using AFM, at large forces the
	ligand-receptor pair becomes entangled and therefore ex-
	pands the unfolding time. A theoretical description of
	this mechanism was given in ref. [28, 29, 30].
	The kinetic data can also be used to determine the as-
	sociated free energy landscape (FEL) [7]. In an initial
	simpliﬁcation we associate the barriers along the stretch-
	ing coordinate as the the kinetic bottlenecks during the
	mechanical unfolding event. Generalizing Bell’s model,
	a recent description of two-state mechanical unfolding in
	the presence of a single transition barrier has been devel-
	oped in [19], with the rate equation
	τ(F) =τ0/parenleftBig
	1−νFx†
	∆G/parenrightBig1−1/ν
	e−∆G
	kBT/parenleftbig
	1−(1−νFx†/∆G)1/ν/parenrightbig
	,
	(1)
	whereνencodes the shape of the barrier. Here x†denotes
	the distance between the barrier and the unfolded basin
	(in a ﬁrst approximation it can be regarded as Findepen-
	dent) and lies on the reaction coordinate along the AFM
	pulling direction. It can be experimentally determined
	by measuring how the stretching force modulates the un-
	folding times τ. The height of the barrier is denoted by
	∆G. Fig. 1 (unfolding times are given by solid red line)
	shows that this single barrier theory is not suﬃcient for
	the full range of forces. As described before, in the higher
	force regime, additional basins have to be included in the
	energy landscape. Models with several metastable basins
	have been called multi-state FEL models [31]. Evidence
	supporting the need of multi-states FEL was conﬁrmed
	by AFM experiments in diﬀerent systems [32, 33].
	To construct a multi-state FEL that incorporates two
	unfolding pathways I and II we use a linear combina-
	tion of eq. (1)-like expressions with diﬀerent shapes and
	barrier heights. Each one of them essentially accounts
	for the distinct barrier along a relevant unfolding route.
	Fitting the stretching data to eq. (1) with a cusp-like4
	2.5 33.5 4F/LBracket1Ε/Slash1/Angstrom/RBracket16.67.6logΤ
	N U I
	FIG. 5: Pathway II with two barriers. Left: dependence of the
	unfolding time on the applied force with the data and the ﬁt
	to the formula (1) for the ﬁrst maximum (lower, in green) and
	for the second maximum (upper, in blue). Right: schematic
	free energy landscape for this pathway, with jammed slipkno t
	in a minimum between two barriers.
	ν= 1/2 approximation (another possibility ν= 2/3 for
	the cubic potential in general leads to similar results [19])
	determines accurately the location and the height of the
	potential barriers. Pathway II involves two barriers: ﬁrst
	until the moment of creation of the intermediate which
	is followed the untieing event. They are characterized by
	(x1,∆G1) and (x2,∆G2) arising respectively from the
	lower and upper ﬁts in Fig. 5 (left). The superposition
	of these two ﬁts gives the overall mean unfolding time for
	pathway II (dotted-dashed curve in green in Fig. 1). For
	the ordinary slipknot unfolding (pathway I), the results
	xIandGIarise from the dashed blue curve in Fig. 1.
	This analysis leads to the results
	x1= 2.3kBT˚A
	ǫ, x2= 0.7kBT˚A
	ǫ, xI= 1.4kBT˚A
	ǫ,
	∆G1= 8.0kBT, ∆G2= 4.2kBT, ∆GI= 4.7kBT.
	We conclude that the free energy landscape consists of
	two “valleys”. The force-dependent probability of choos-
	ing one of the valleys during stretching depends on the
	details of the protein structure. It is determined from our
	simulations as shown in Fig. 4. Using these probability
	values and the parameters above for xand ∆G, we can
	accurately represent the simulation data using a linear
	combination of equations of the form (1). This agreement
	supports our analytical analysis and generalizes eq. (1)
	for the full of range forces. In addition it demonstrates
	that structure-based models suﬃciently capture the ma-
	jor geometrical properties of a slipknotted protein. A
	schematic representation of the free energy landscape for
	pathway II is shown in Fig. 5 (right).
	Summarizing, we have analyzed the process of tighten-
	ing of the slipknot in protein 1e2i and determined the cor-
	responding free energy landscape. Its main feature is the
	presence of a metastable conﬁguration with a tightened
	slipknot, which is observed for suﬃciently large pulling
	forces. This phenomenon does not exist for uniformly
	elastic polymers. In this Letter we concentrated on pro-
	tein 1e2i but similar behavior has also been observed forother proteins with slipknots, e.g. 1p6x. Our results
	provide testable predictions that can now be veriﬁed by
	AFM stretching experiments.
	We appreciate useful comments of O. Dudko. The
	work of J.S. was supported by the Center for Theo-
	retical Biological Physics sponsored by the NSF (Grant
	PHY-0822283) with additional support from NSF-MCB-
	0543906. P.S. acknowledges the support of Hum-
	boldt Fellowship, DOE grant DE-FG03-92ER40701FG-
	02, Marie-Curie IOF Fellowship, and Foundation for Pol-
	ish Science.
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